DE3727207A1 - Device for recombining hydrogen and oxygen - Google Patents

Abstract

For recombining hydrogen and oxygen with the help of a catalyst, a catalyst body (2) is located in a tube (1) running vertically, whose length is at least twice its diameter, at a distance from the inner wall (5) of the tube. The ends of the tube (1) are provided with stoppers (14) that open as a function of pressure and/or temperature. The device is employed in particular in the containment of a water-cooled nuclear reactor. <IMAGE>

Description

The invention relates to a device for recombining Hydrogen and oxygen with the help of a catalyst. Such Devices are, as in the German patent 30 04 677 is described, in particular for dismantling the safe Unit container of a water-cooled nuclear reactor plant turned on closed hydrogen used. According to the mentioned patent ignition sources are distributed in the safety container, which can be catalytic in nature. With the ignition sources should the hydrogen that may be generated in the event of an accident Flared when the lower ignition limit is reached. So that is open combustion is meant.

The flaring is therefore in the patent 30 04 677 considered harmless, because it creates gas for a short time cloud temperatures of maximum 500 ° C do no damage can. Nevertheless, the invention is based on the task that Recombination of hydrogen and oxygen with the help of a To enable catalyst in a device where free Gas clouds can be avoided.

The device according to the invention is designed so that in a vertical pipe, the length of which is at least that A catalyst body is twice its diameter is ordered and that the end faces of the tube with pressure dependent and / or temperature-dependent closures are provided.

In the device according to the invention, the Catalyst body, the catalyst material in particular Palladium or platinum has a recombination already in the Range of non-ignitable hydrogen concentrations. At  this recombination known as "cold ignition" occurs also a warming. However, this is much lower than with the known flaring. Especially with little what is recombination with its heating up limits the area of the catalyst body and this is through the tube, which advantageously surrounds it at a distance, practical shielded from the outside. Nevertheless, the warming provides the kindling of a gas flow, the further gas through the Pipe and over the catalyst body as long as the gas contains only small percentages of hydrogen.

From DE-PS 30 35 103 it is known that one in the Safety cover of a nuclear power plant with recombination provides directions for hydrogen and oxygen shafts, in which heating devices a gas flow through chimney effect set in motion. These shafts, which also have shut-off devices may contain, but should be at least half the height the security envelope, i.e. over 20 m and more. In this Electric heaters are said to have temperatures of over 50 kW Reach 600 ° C to burn existing hydrogen. In contrast, the devices according to the invention are none Require energy supply and pipe lengths of at most 2 m have so small and easy to install that they are practical used everywhere, especially for retrofitting can be.

The inside can also be used to improve the catalytic effect side of the tube may be coated with catalyst material. The then there is heating in comparison to the cooling surface of the pipe low.

It is also advantageous if below the catalyst body pers a porous substance is arranged, the silver nitrate contains. This can be achieved that the effectiveness of Catalyst not ver by airborne catalyst poisons is reduced. The porous substance can advantageously be a  Ceramic body provided with silver nitrate, e.g. by dipping in a silver nitrate solution.

A particularly advantageous development of the invention be is that wires are attached to the catalyst body, the catalyst material include and in one under the Kataly protruding space in the interior of the tube. The Wires blended with silver nitrate through the porous substance can be caused by the heating of the catalyst body in turn heated up. They therefore form with their free ends an ignition source with which the gas is then used for a ignition sufficient concentration of about 4% hydrogen is enough, is burned before it reaches the catalyst body goes through. Also for combustion is different from Known given a shield through the tube, so that large-scale deflagrations are excluded.

The catalyst body can have a honeycomb structure and with Be coated catalyst material. The honeycomb can body made of a metallic or ceramic carrier material exist that are made in a cubic or cylindrical shape becomes. The channels running inside parallel to the pipe axis are coated in a known manner with palladium or platinum.

Another embodiment of the catalyst body exists in that the catalyst body in the direction of the tube axis stacked wire nets includes and that on individual Crossings of the wire nets in the direction of the pipe axis running wires are braided. The wire nets can before or after unification, e.g. galvanically with the Catalyst material to be coated.

With the closures at the ends of the tube is secured represents that the catalyst effect is not due to the ambient atmosphere is reduced before recombination is required is. Known membranes can be made from an elevated membrane  Temperature melting plastic may be provided. they give the catalyst material is free if there is an accident in which Hydrogen is generated, an elevated temperature occurs. A another possibility is that membranes through the overpressure arising in the event of a fault.

The closures can also advantageously be in the form of bimetal sheet metal. Here is the temperature change resulting deformation to open passage cross-sections used. Conveniently, the pipe cross section can be made with a Variety of metal strips to be covered, because then already at small changes in temperature exposed a large cross section can be.

For a more detailed explanation of the invention are based on the Drawings described exemplary embodiments. The shows

Fig. 1 shows a device according to the invention in a perspective view, partly in section, the

Fig. 2 shows another embodiment of the catalyst body in a view and

Fig. 3 shows a third embodiment of the catalyst body also in a view.

The device according to the invention comprises a vertically flexible metal tube 1 , for example a steel tube, with a diameter of 200 mm and a length of 600 mm. Length and diameter are therefore 3: 1. The wall thickness is about 3 mm.

In the upper area of the tube 1 , a catalyst body 2 is arranged, which has a diameter that is approximately 30 mm smaller than the inside diameter of the tube 1 . Its length is 150 mm. The catalyst body 2 is fixed with projections 3 of the inner tube wall, which ensure that the heat transfer between the catalyst body 2 and the tube 1 is as low as possible. The projections can be formed in a punctiform manner and can be produced by indentations from the outside.

In the exemplary embodiment in FIG. 1, the catalyst body 2 consists of a ceramic material with a honeycomb structure, so that a plurality of channels 4 running parallel to the tube axis and having a square cross section are created. The channel cross-section could also be triangular, hexagonal or round, for example, as long as a large surface area is achieved in relation to the volume. The catalyst body is coated in the region of the channels 4 and on its outside with palladium and / or platinum as the catalyst material. This coating is also applied to the inside 5 of the tube 1 .

Under the catalyst body 2 , a ceramic body 7 is provided as the porous substance, which fills the tube cross section, but is only 30 mm high. It is used for the chemical neutralization of catalyst poisons and is provided with silver nitrate. Instead of the ceramic body 7 , a pressed fiber structure, for example in the form of wire wool or asbestos fabric, could also be used. It is important that the flow resistance is relatively small.

In a section of the catalyst body 2 it is shown that a wire 9 is attached to the wall of one of the channels 4 , which is wholly or at least partially made of catalyst material. The connection with the catalyst material should have good thermal conductivity there. Therefore, the wire 9 is turned to a winding 10 at the fastening point. This is connected to the catalyst material of the wall by welding, soldering or even by gluing.

As can be seen, several wires 9 projecting over the tube cross-section project downward through the porous substance 7 into a free space 12 . In these, their free ends 11 can act as ignition sources which ignite the inflowing hydrogen when the hydrogen concentration is greater than 4%. Previously, catalytic recombinations in the region of the catalyst body 2 heat up the catalyst body itself and the wires 10 that are in a thermally conductive connection therewith.

On the end faces of the tube 1 , as shown in FIG. 1 on the top, closures 14 are provided which open depending on the temperature. In the exemplary embodiment, bimetallic strips 15 running parallel to one another are provided in four segments, which bulge outward when there is a change in temperature and thus enable a gas flow which is fanned by the heating of gas in the tube 1 . An identical closure on the lower end face is not visible.

The new device works completely without external energy sources. It is maintenance-free and can therefore be used anywhere in the interior of a water-cooled nuclear reactor, in particular a pressurized water reactor. In the event of a fault, the closures 14 on the pipe 1 are opened by the increased pressures and temperatures that then occur. The medium in the safety envelope therefore has access to the inside of the pipe. Hydrogen present in this medium is recombined catalytically to water with the oxygen also present in the region of the catalyst body 2 . The catalyst body heats up during this exothermic reaction. This initiates a gas flow that leads in the direction of arrow 16 from below through the vertical pipe. This adds 2 new medium to the catalyst body, the hydrogen content of which is reduced by recombination.

If the hydrogen content exceeds the ignition limit of 4%, the wires 9 heated with the catalyst body 2 lead to ignition, so that only unburned hydrogen portions need to be recombined in the region of the catalyst body itself. The pipe 1 ensures that the aforementioned combustion as well as the catalytic heating take place in a shielded room and do not lead to uncontrolled extensions.

In the embodiment according to FIG. 2, the catalyst body 2 ', a winding of a sheet metal strip 16, which, as the figure shows, profiled in the direction of the winding axis with longitudinal corrugations. The sheet metal coil 2 'is provided with catalyst material. This also extends to the projections of the winding, which act as ignition wires 9 '.

In the embodiment according to Fig. 3, the catalyst body 2 '' consists of stacked wire nets 17 with the circular cross-section shown in the figure. In the wire networks are transverse to the network level ignition wires 9 '' interwoven th. Nets 17 and ignition wires 9 '' can be coated together with catalyst material.

Claims (13)

1. Apparatus for the recombination of hydrogen and oxygen with the aid of a catalyst, characterized in that in a vertically extending tube ( 1 ), the length of which is at least twice its diameter, a catalyst body ( 2 ) is arranged and that the end faces of the Pipe ( 1 ) with pressure-dependent and / or temperature-dependent opening closures ( 14 ) are provided. 2. Device according to claim 1, characterized in that the catalyst body ( 2 ) is arranged at a distance from the inner tube wall ( 5 ). 3. Apparatus according to claim 1 or 2, characterized in that the inside ( 5 ) of the tube ( 1 ) is coated with catalyst material. 4. Apparatus according to claim 1, 2 or 3, characterized in that a porous substance ( 7 ) is arranged below the catalyst body ( 2 ), which contains silver nitrate. 5. The device according to claim 4, characterized in that the porous substance is a ceramic body ( 7 ) which is provided with silver nitrate. 6. Device according to one of claims 1 to 5, characterized in that on the catalyst body ( 2 ) wires ( 9 ) are attached, comprising the catalyst material and in a Kataly sator body ( 2 ) located free space ( 12 ) inside the tube ( 1 ) protrude. 7. The device according to claim 4 or 5 and 6, characterized in that the wires ( 9 ) through the porous substance ( 7 ). 8. Device according to one of claims 1 to 7, characterized in that the catalyst body ( 2 ) has a honeycomb structure and is coated with catalyst material. 9. Device according to one of claims 1 to 8, characterized in that the catalyst body ( 2 '') in the direction of the tube axis comprises stacked wire nets ( 17 ) and that at individual intersections of the wire nets ( 17 ) extending in the direction of the tube axis wires ( 9 '') Are woven in. 10. Device according to one of claims 1 to 9, characterized in that membranes are provided as closures ( 14 ) made of a plastic melting at elevated temperatures. 11. Device according to one of claims 1 to 9, characterized in that bimetallic sheets are provided as closures ( 14 ). 12. The apparatus according to claim 11, characterized in that the tube cross section is covered with a plurality of sheet metal strips ( 15 ). 13. Use of the device according to one of claims 1 to 12 in the safety case of a water-cooled core reactor, in particular a pressurized water reactor.