DE3908823C1 - Steam curtain system - Google Patents

Abstract

Steam curtain systems for reducing damage in the case of heavy gases liberated in the course of a major accident contain a nozzle pipe (8) which surrounds the hazardous area, a heavy-gas detector system and a steam source, from which, in the case of a major accident, steam is injected under pressure into the nozzle pipe. In order to shorten the interval between the steam supply being switched on and the formation of a complete steam curtain, it is provided that the nozzle pipe (8) either consist in its entirety of pressure-proof plastic having a low thermal conductivity, or of a metal pipe (10) which on its inner wall is provided with a thermal insulating layer (11). <IMAGE>

Description

The invention relates to a steam curtain system for damage reduction in the case of heavy gases released from accidents - in particular with toxic gases - which comprises a nozzle pipe surrounding the danger zone, a heavy gas detector device and a steam source, from which steam is introduced under pressure into the nozzle pipe in the detected accident.

Steam curtain systems are used as a safety measure primarily intended for chemical plants, where the Task comes up when an accident occurs Heavy gas release the formation and spread of Prevent heavy gas clouds from forming Intoxication or an ignitable mixture avoid. In addition, the steam added chemical the harmful gas through reactions in non-hazardous products are converted. This will the steam curtain between the source of danger and the positioned to be protected area. With the known Steam curtain systems is a steel nozzle tube with  suitably shaped for the release of steam Exits used, which are Bores in the nozzle tube or on the nozzle tube welded socket with screwed on Nozzles can act. When switched on Steam supply flows from each individual outlet opening steam jets off, and the real one The steam curtain then forms as a collective of the a short distance behind the outlet openings already overlapping individual steam jets. From the steam curtain sucks this on the side facing the leak Heavy gas and air from the side facing away from the leak. Air is released from both above the heavy gas layer Mixed in sides of the curtain. That within the Resulting steam curtain mixture, Heavy gas and air then go up vertically transported. Steam is predominantly water vapor of high pressure or steam with admixtures used, usually in the steam networks the plants operating pressures in the range up to a few 10 bar g are available.

A disadvantage of the known steam curtain systems however, that in the event of a malfunction a proportionate long time passes before a fully effective steam curtain is formed. Like practical experience and have shown experimental trials a period of up to about ten minutes can delete and just at the beginning of this period Heavy gas in significant quantities over the still build-up vapor barrier into the one to be protected Reach the area and there have a damaging effect to lead.  

The invention has for its object in a generic steam curtain system the time span between occurrence of the accident and training of the full steam curtain to an uncritical value reduce.

This object is achieved according to the invention achieved that either a pressure-resistant plastic Nozzle tube of low thermal conductivity or a metallic nozzle tube is provided, which at its Ver interior wall with a thermal insulation layer see is. Surprisingly, by this measure took the formation of the steam curtain in the event of an accident accelerated considerably, since it is already short After switching on the steam supply, steam with saturated steam temperature emerges from the nozzle openings. On the other hand can be observed when working with steel nozzle pipes make sure that the superheated steam is initially a large part gives off its heat to the nozzle tube, which lasts continues until the nozzle tube reaches saturated steam temperature is heated up. Until this state is reached to a considerable extent within the nozzle tube a condensation of the steam, which is one of the causes for the strong delay in the Training of the steam curtain is.

The invention can be done in various ways realize. For example, the nozzle tube can be made from one with a plastic interior finish Steel pipe exist. Alternatively, it is also possible as Nozzle pipe a steel pipe with inserted art to use fabric tube.  

In a further development of the invention, it can be provided that that the thermal insulation layer with a thin, strong is provided heat-conducting layer, the heat conductive layer of an evaporated metal Layer, for example made of copper.

It can also be provided that the nozzles Plastic or with a plastic liner provided metal parts exist.

These measures will help to even out the temperature development within the whole Nozzle tube ensured.

According to a very advantageous development of Invention can be provided that the operational moderate steam supply to a close to the Nozzle tube arranged, suddenly released Lock is constantly in contact with steam, with the lock off a rupture disc can exist, which by means of a firing pin controlled depending on the detectors drive is destructible. Through these measures the introduction of steam into the nozzle tube and thus the formation of the steam curtain accelerated considerably. To the after an accident or for maintenance purposes To be able to shut off the steam supply is expedient the rupture disc on the side of the steam supply line Shut-off valve upstream.

The invention is described below with reference to the drawing explained in more detail in the shows

Fig. 1 is a protected by a steam curtain chemical plant,

Fig. 2 is a sketch for explaining the operation of the vapor curtain,

Fig. 3 is a schematic representation of the curve of the efficiency at power of the vapor curtain,

Fig. 4 shows a portion of a steam curtain system with nozzle pipe,

Fig. 5 shows a section according to line VV in Fig. 4,

Fig. 6 in an enlarged scale a cross section through a nozzle tube according to the invention,

Fig. 7 on an enlarged scale in cross section a second embodiment of the nozzle tube according to the invention and

Fig. 8 shows a third embodiment according to the invention.

Fig. 1 illustrates a chemical plant 1, which is surrounded by a steam curtain system 2 on the side of the protected area, for example, to the work towards fence 3. If emerging heavy gas 4 is detected, the steam supply to the steam curtain system 2 is automatically switched on and forms a steam curtain 5 , which consists of a steam-heavy gas-air mixture, as illustrated in FIG. 2, the steam either only from water or a mixture of water and added special chemicals.

In Fig. 3 with the solid curve 6, the time course of the concentration development C of the heavy gas in the area of the steam curtain system is given again, and the dashed curve 7 shows the development of the effect factor W. If the steam supply to the nozzle pipe 2 is switched on at the time t ₁ , it takes a certain period of time until the time t ₂ before the concentration is reduced sufficiently, and this time period should be kept as short as possible.

Fig. 4 shows a perspective view of a portion of the steam curtain system with nozzle tube 8 , which is seen here with a plurality of attached nozzles 9 ver. As can be seen from Fig. 6, the nozzle tube consists of an outer steel jacket 10 , which is provided on its inner wall with a thermal insulation layer 11 , which largely excludes steam condensation in the nozzle tube when switching on and ensures that after a very short time from the Nozzles 9 hot steam jets under high pressure and so the formation of the steam curtain is initiated and carried out in the shortest possible time.

Alternatively, the nozzle tube can also consist of a pressure-resistant plastic tube 12 , cf. Fig. 7.

A further development is illustrated in FIG. 8, in which the nozzle tube provided with a thermal inner lining is again provided on the inside with a highly thermally conductive thin metal layer 13 , which can be, for example, an evaporated copper layer.

The operational steam supply line 14 is steam leading up to a lock 15 arranged near the nozzle tube 8 . The lock 15 consists of a rupture disk 16 , which can be destroyed by means of a firing pin 17 which can be triggered. A shut-off valve 18 is connected upstream of the lock.

Claims (9)

1. Steam curtain system for damage reduction in the case of heavy gases released from accidents - in particular toxic gases - consisting of a nozzle pipe surrounding the danger zone, a heavy gas detector system and a steam source from which steam is introduced into the nozzle pipe under pressure in the detected accident, characterized in that the nozzle tube ( 8 ) either consists entirely of pressure-resistant plastic with low thermal conductivity or consists of a metal tube ( 10 ) which is provided on its inner wall with a thermal insulation layer ( 11 ). 2. Steam curtain system according to claim 1, characterized in that the nozzle tube ( 8 ) consists of a steel tube ( 10 ), on the inner wall of which a plastic lacquer layer is applied as an insulation layer ( 11 ). 3. Steam curtain system according to claim 1, characterized in that the nozzle tube ( 8 ) from a steel tube ( 10 ) with inserted, the insulation layer ( 11 ) forming tube made of heat-insulating material, for. B. plastic. 4. Steam curtain system according to one of claims 1 to 3, characterized in that the thermal insulation layer ( 11 ) is provided with a thin, highly thermally conductive layer ( 13 ). 5. Steam curtain system according to claim 4, characterized in that the heat-conducting layer ( 13 ) consists of a vapor-deposited metal layer, for example made of copper. 6. Steam curtain system according to claim 1 and one of claims 2 to 5, characterized in that the nozzles ( 9 ) consist of plastic or metal parts provided with art lining. 7. Steam curtain system according to one or more of claims 1 to 6, characterized in that the operational steam feed line ( 14 ) up to a close in front of the nozzle pipe ( 8 ) arranged, suddenly releasable lock ( 15 ) is constantly steam-carrying. 8. Steam curtain system according to claim 7, characterized in that the lock ( 15 ) consists of a rupture disc ( 16 ) which is destructible by means of a controlled by detectors percussion bolt drive. 9. Steam curtain system according to claim 8, characterized in that the rupture disc ( 16 ) on the side of the steam feed line ( 14 ) is preceded by a shut-off valve ( 18 ).