DE3104260A1 - Device for storing hydrogen and for ducting it to the demand points of a water-cooled nuclear reactor plant - Google Patents

Abstract

The object of the invention is to reduce, in a device of this type, the risk of a hydrogen explosion by storing and ducting the hydrogen in a different manner. To this end it is provided that the hydrogen be stored as a metal hydride (5) and that this be connected via a low-pressure line (15) to the demand points (16). In order to control the amount of hydrogen dispensed, the metal hydride (5) is provided with heating (6) and cooling elements (7). A pressure vessel fitted with an insulation (4) encloses the metal hydride charge. <IMAGE>

Description

Device for the storage of hydrogen and its

Introduction to the places where a water-cooled nuclear reactor is required.

The invention relates to a device for storing hydrogen and to bring it to the point of need of a water-cooled nuclear reactor plant.

In a water-cooled nuclear reactor facility, there are several Systems a need for hydrogen. So z. i the primary system for the purpose of Conditioning via a gas cushion or the hydrogen volume compensation system fed.

So far, the hydrogen quantities required for this have been obtained from a compressed gas flat storage facility brought up to the relevant points of need via pressure lines. At this The type of storage and supply requires a high level of control engineering effort. to avoid the risk of a hydrogen explosion. Despite this effort, there is a considerable residual risk for the formation of local ignitable hydrogen / air mixtures. The lines are long because the pressurized gas cylinders are in adjoining rooms for safety reasons are stored.

The invention therefore has the task of storing hydrogen and its introduction at the point of need of a water-cooled nuclear reactor plant to act in such a way, that the identified disadvantages are avoided and thus the risk of a hydrogen explosion is considerably reduced.

This object is achieved according to the invention in that the required Hydrogen is stored as Netall-Rydrid, that the same over a pipe system low thickness connected to the feed points and can be heated and cooled.

The pressure in the hydride storage is low because the hydrogen is in chemical bound form is present. For example, the hydrogen partial pressure is from Magnesium hydride at room temperature 10-7 7 bar. Should hydrogen for the supply released to a point of demand such as the primary coolant system, then the metal hydride is heated.

The hydrogen gas then flowing out shows e.g. when it is heated of the hydride to 2000C to a pressure of 1 bar, so that the points of need leading Lei-tun system of chewing is burdened.

Another advantage of the facility is that of sifting the need of hydrogen via the temperature of the metal hydride @ can be regulated.

The metal hydride is preferably in one of heating and cooling elements enclosed pressure vessel included, with a outside of the pressure vessel Isolation is provided.

This is particularly the case with pressure vessels arranged horizontally shown as advantageous to attach the heating and cooling elements in a meandering shape. Through this can be a liquid cooling or heating medium, e.g. in the event of a necessary repair easier to remove from the elements.

Another design of the device provides that the Metallhaydrid surrounded by an insulation adjoining the inner wall of the pressure vessel is that heating and cooling elements penetrate the metal hydride and through the insulation and the pressure vessel wall are guided. Direct contact with the Metal hydrides with the heating or.

The device can be operated more economically with cooling elements.

With the mobile training of the device, the same can be outside the nuclear reactor plant with appropriate cooling and then to the intended Transport location within the nuclear reactor facility.

According to a further embodiment, the insulation is designed to be fireproof. This ensures that the hydrogen only flows off slowly in the event of a fire and practically cannot feed the fire.

With the aid of the schematic drawings of FIGS. 1-3, two exemplary embodiments are illustrated of the facility. They show: FIG. 1 a longitudinal section through a Device, Fig. 2 is a longitudinal section through a differently designed device and FIG. 3 shows a section along the line III-III in FIG. 2.

Fig. 1 shows a trolley 1 with one arranged thereon Container 2, which encloses a pressure vessel 3 while leaving a gap. In the space there is a fire-resistant one for the purpose of thermal insulation Insulation 4. The pressure vessel has a magnesium hydride filling5 in which the hydrogen is reversibly chemically bound. Electric heating elements 6 and cooling elements 7 through which water flows enclose the pressure vessel jacket in a spiral or meandering. One each provided with a coupling piece 8 and a fitting 9 Line 10 provides the feed or

Discharge line for the water circuit of the cooling element 7.

The temperature of the metal hydride, which in this example is a magnesium hydride is, is monitored with the aid of a temperature sensor 11. With the heating and cooling element is the pressure within the magnesium hydride and thus also the demand infinitely variable on hydrogen. A hydrogen extraction line 12, which at a Heating the magnesium hydride to 2000C with a Print from 1 bar is applied, leads from the pressure vessel 3 via a shut-off device 13, a Coupling connection 14 and a low pressure line 15 to the point of demand 16 S in a nuclear reactor facility not shown. A branch 17 of the hydrofoil management 12 leads via a safety valve 18 to a receptacle (not shown) directed blow-off line 19.

The pressure in the hydrogen extraction line is determined by the measuring device 20 monitors. A stop bracket 21 connects to the container 2, which is used for protection which also serves the fittings and lines protruding from the container.

Fig. 2 shows a pressure vessel 3 to which the consoles 22 for Receiving the wheel axles 24 are attached directly to the wheels 25. So is The facility can also be moved after this training. Along the inner wall of the pressure vessel an insulation 4 made of aluminum oxide is arranged. In the insulation is a metal hydride 5, such as a magnesium-nickel-hydride filling. The metal hydride is of electrical heating elements 6 and cooling elements through which water flows 7 crossed. Two tubes of the Cooling element bridged by a connecting piece 27, so there is a closed cooling circuit arises, which is provided with a supply or discharge line 10. The power supply for the electrical heating elements 6 is indicated at 28. iSin sieve plate 29 from Metal or a sintered plate 30 made of ceramic oxide delimits the metal-hydride filling 5 on the front. The hydrogen removal line 12 leads over from the pressure vessel 3 a shut-off valve 13, a coupling connection 14 and a low-pressure line 15 leads to a demand point 16. branch 17 of the hydrogen removal line 12 leads Via a safety valve 18 to a receiving container (not shown) connected blow-off line 19. A stop bracket 21 is attached to the pressure vessel, which serves to protect the fittings and lines protruding from the pressure vessel.

A temperature sensor 11 and a measuring device 20 are used for monitoring the hydride temperature and the pressure vessel internal pressure provided.

From FIG. 3, which shows a cross section of FIG. 2, there are webs 31 to stabilize the heating and cooling elements can be seen.

Claims (6)

Claims 1. Device for storing hydrogen and for its introduction to the points of need of a water-cooled nuclear reactor plant, characterized in that the required hydrogen is stored as a metal hydride (5) is that the same via a low pressure line (15) with the demand points (16) connected and can be heated and cooled. 2. Device according to claim 1, characterized in that the metal hydride enclosed in a pressure vessel (7) surrounded by stimulus (6) and cooling elements (7) is-t, insulation (4) being provided outside the pressure vessel. 3. Device according to claim 2, characterized in that the heating and cooling elements are arranged in a meandering manner. 4. Device according to claim 1, characterized in that the metal hydride from an insulation adjoining the inner wall of the pressure vessel (3) (4) is surrounded that heating and Kiblelemente penetrate the metal hydride as well are passed through the insulation and the pressure vessel wall. 5. Device according to one of claims 1-4, characterized in that that it is designed to be mobile. 6. Device according to claims 2 or 4, characterized in that that the insulation is fireproof.