EP1274487A1

EP1274487A1 - System for ensuring evacuation and rescue from the effects of smoke, heat and pollutants

Info

Publication number: EP1274487A1
Application number: EP01937977A
Authority: EP
Inventors: Axel Kretzschmar; Gerd MÜHLENBRUCH; Helmut Witwar
Original assignee: Kretzschmar Axel Drrernathabil
Current assignee: Kretzschmar Axel Drrernathabil
Priority date: 2000-04-20
Filing date: 2001-04-07
Publication date: 2003-01-15
Also published as: NO316960B1; CA2405564A1; JP2003533250A; DE10019537A1; NO20024870D0; SI20909A; DE10019537C2; NO20024870L; WO2001080954A1

Abstract

The invention relates to a system for ensuring evacuation and rescue from the effects of smoke, heat and pollutants in areas with long evacuation routes, such as mining installations, underground transport systems, or similar. Said system takes advantage of the characteristics of a mist of water, which is generated by misting means, in such a way that the air lying in the area below the layer of fumes can be respired for a long period of time and its clarity can at least be maintained, so that the direction of evacuation remains visible. According to the invention, the sprinkler nozzles (3), which generate the mist, are fixed to sprinkler arches (2) that are positioned along the entire length of the area and/or its evacuation routes, one behind the other, transversally to the direction of evacuation, following the clearance contours of the area and/or the evacuation routes. The arch-type arrangement of the sprinkler nozzles (3) over the entire length of the areas and evacuation routes divides the structural installations into sections, which do not impede the basic air flow (6) present in the installation, in such a way that the smoke or pollutant flow is not accumulated by the mist that is produced.

Description

Arrangement to secure the escape and rescue under smoke, heat and pollutants

The invention relates to an arrangement for securing the escape and rescue under smoke, heat and pollution from rooms with long escape routes such as mines, underground transport systems and. ä.

In pilot plants it is e.g. For example, it is common to install systems equipped with sprinklers for fire fighting and rescue from underground rooms, especially road and rail tunnels. The inadequacy of such systems has been shown both in the event of an accident and in practical tests. The reasons for this can be seen above all in the relatively large drops of water emerging from the sprinklers at high speed, which are therefore unable to bind the smoke and pollutant particles. Rather, due to their high exit velocity and size, they destroy the hot flue gas layer moving outdoors with the natural flow or forced through suction systems. The result is that the flue gas layer mixes with the low-flue gas layer underneath, thereby considerably restricting sight and breathing for the refugees and the rescue personnel, making it more difficult to escape and deploy the rescue personnel. In addition, the high water intensities required in sprinkler systems partially extinguish the fire. However, the extinguished areas of the fire pose an extreme risk of reignition. Flammable gases and vapors spread unnoticed and ignite again at the next opportunity. The resulting deflagrations or even explosions have just in underground systems such. B. traffic tunnels, devastating consequences. This danger is particularly great, particularly in cases where flammable liquids are involved in the fire, which is often the case with fires in vehicles in tunnels. Plants that work on the basis of the method described in DE-PS 195 14 923 C2 for securing escape and rescue under smoke and heat exposure are much better suited for containing the consequences of fires. The principle on which this invention is based is that the smoke and pollutant concentration is determined by the finest

To reduce water droplets or water mist, hereinafter referred to as mist, so as to improve breathing and visibility in the endangered area, so that escape and rescue from the tunnel is made considerably easier. In addition, the falling fog fire has an insulating effect, sporadic, spatially limited extinguishing of the fire is avoided. This is achieved by a mist with a low exit and / or propagation speed, the particle density of which has the concentration required for the smoke, heat and pollutant compound. The particle size of the mist is set so that the water particles slowly sink from their starting point without impairing the view in the room. Similar to sprinkler systems, the water mist nozzles are arranged in the upper area of the tunnel along its ceiling, whereby their exit direction can vary in the direction parallel and perpendicular to the ceiling. A section-wise arrangement of the water mist nozzles enables their operation in alternating cycles. Installed sensors detect the fire and trigger the water mist nozzles installed in the immediate vicinity of the fire.

Practical testing has shown significant advantages over conventional sprinkler systems, but the desired effect has not yet been satisfactorily achieved by this procedure. It was also disadvantageous here that the natural flow of the smoke gas layer was still too strongly influenced by the emerging mist and therefore there was still mixing with the low smoke gas layer, although the cleaning effect of the smoke by the fine mist droplets was demonstrably present.

Another well-known form of fighting smoke in enclosed spaces is the use of water curtains. For this purpose Extinguishing agent outlet devices arranged so that the extinguishing agent emerging in the event of fire forms a curtain impenetrable to the flue gases. A sufficient effect here, however, only occurs in combination with powerful smoke extraction devices, which must then also be designed for the entire space sealed off between the water curtains. Apart from the high effort required for this, such arrangements are unsuitable for the escape and rescue of people, since orientation within such a space is completely impossible. As already mentioned, partitioning water curtains are always tied to powerful smoke extraction systems. The water-carrying systems must therefore always be arranged so that there is at least one smoke extraction system between them. The spaces between two water curtains can extend up to 100 m.

The invention is therefore based on the problem of providing an arrangement for securing the escape and rescue under smoke, heat and pollutant pollution using a fog-generating means, which exploits the properties of the fog in such a way that the air at least in the area can be kept breathable and at least translucent underneath the flue gas layer for a long time, so that the direction of escape remains recognizable.

According to the invention, the object is achieved by the features of the first patent claim. The following claims 2 and 3 relate to expedient refinements of the arrangement.

Due to the arched arrangement of the spray nozzles according to the invention over the entire length of the rooms and escape routes, the entire structural system is divided into sections. These sections are not mutually isolated areas, as is the case with water curtains, but rather leave the smoke or pollutant flow in its direction determined by the air flow present and not affected by the water mist pull off freely. This means that neither the arrangement of the spray arches transverse to the direction of the air flow nor the mist emerging from the nozzles hinder the air flow, which carries the smoke and pollutant flow unimpeded in its natural or forced flow. The low exhaust impulse of the mist reduces the swirling of the smoke. Rather, the mist nozzles directed in the direction of the flow of the smoke and pollutant flow support its flow. At the same time, the floating water droplets bind the dust, soot and pollutant particles contained in the smoke and sink with them to the ground. This is tantamount to washing the smoke, which makes it cleaner from section to section, ie more translucent, breathable and also cooler. The slow sinking of the cleaned smoke with the distance from the source of the fire is now less dangerous for people. The overall damp atmosphere in the tunnel has a fire-insulating and anti-inflammatory effect.

The arrangement of the mist nozzles per spray bend depends on their spray characteristics. The spray cones must overlap slightly, with all spray cones covering the cross-section of the entire room near the bend.

The distance between the spray arches within the tunnel depends on structural, safety and, not least, economic considerations. The shorter the distance, the more intensively the flue gas stream is cleaned, the safer escape and rescue are. In the case of larger distances, the reasonableness of the length of the escape route must also be taken into account.

When operating the system in the event of an accident, it is advantageous to also activate a spray elbow in front of the source of the fire in order to reliably prevent fire and flue gas from spreading against the air flow. The number of spray arches arranged in the direction of the air flow after the source of the fire depends on the intensity of the smoke and harmful gas development. A pivotable arrangement and control of the exit angle of the mist nozzles allows a targeted adaptation of the mist outlet to the flow conditions in the escape route to be protected. To adapt the spray direction of the mist nozzles to the flow conditions, it is also possible to always provide two parallel spray arches with mist nozzles spraying in the opposite direction and to make the water supply to these controllable.

By means of the arrangement according to the invention, using relatively simple and known constructional means, it has been possible to utilize the properties of the fog in such a way that escape and rescue from rooms with long escape routes can take place much more safely.

The invention will be explained in more detail below using an example. Show in the accompanying drawing

1 shows the diagram of a system according to the invention installed in a tunnel after the fire has broken out, but before it is activated and FIG. 2 shows the system according to the invention after the fire has broken out

The arrangement described in the present exemplary embodiment uses a very effective and cost-effective detection of a fire, which is not the subject of this invention, but uses the means according to the invention for suctioning and directing the flue gases. In this context, reference is made to patent application DE 198 588 77.1. The details and mode of operation of fire detection are therefore not discussed in detail in the following description. As can be seen from FIG. 1, three spray pipe bends 2 are arranged on the section of a traffic tunnel 1 shown, each of which bears a plurality of spray nozzles 3. The spray nozzles 3 are pivotally arranged so that they can discharge the fog in a range between 0 and 90 ° to the driving directions of the traffic tunnel 1. As already mentioned, the spray nozzles 3 are used in the normal operating state for the permanent suction of the tunnel gases to be passed on to a detector device (not shown in more detail). The spray pipe bends 2 are fastened to the wall perpendicular to the direction of travel, following the shape of the clearance profile of the traffic tunnel 1. The installation of the system therefore does not result in any restrictions on the height or width of the space available for vehicle traffic. The spray pipe bends 2 are connected to a water supply 4. This can be achieved without any special additional effort if an extinguishing water pipe is installed in the tunnel.

At the bottom of the traffic tunnel 1, a source of fire 5 can also be seen, which leads to intensive smoke development. This spreads mainly in Direction of the air flow 6, which is predominant in the traffic tunnel 1, from below the tunnel ceiling. A smaller part of the flue gas flow also moves against the air flow 6. The development and spread of flue gas is characterized by hatching from short horizontal lines.

The mode of operation of the invention will be explained below with reference to the system shown in FIG. 2 that is in operation after fire detection. For reasons of better clarity of the drawing, only the middle spray bow 2 and here only three of the

Spray nozzles 3 shown in function. The range and the direction of the emerging fog were illustrated by spray cones 7, which are shown as a spatial grid ^ network. However, all the spray nozzles 3 of all three spray arches 2 are in operation. It can also be seen that an active spray arch 2, viewed in the direction of the air flow 6, precedes the source of the fire 5 and the other two active spray arches 2 are arranged downstream of the source of the fire 5. The activity of the spray nozzles 3 is illustrated in all spray bows 2 by gray gate-shaped areas 8. In fact, the action of the spray nozzles 2 in action can also be compared or explained with a fog gate. It can also be clearly seen that the spray direction of the

Spray cone 7 points in the direction of the smoke flow, ie also in the direction of the air flow 6. Part of the spray nozzles 3 is directed obliquely downwards. The effect of the three spray arches 2 as fog gates for the flue gas flow is different: the spray arch 2 located in front of the source of the fire 5 prevents the flue gases from passing through against the air flow 6. This area is therefore kept smoke-free for firefighters and rescue teams. At the same time, even before they pass through the second spray arc 2, the smoke gases are released for the first time under the action of the mist from some of the smoke and pollutants which sink down with the mist droplets. Under the action of the mist of the second spray arc 2, the flue gas stream is freed again from its particles which hinder breathing and vision and is also cooled further. The gradual cleaning through the action of the mist of the spray Arch 2 was illustrated by a less dense hatching of the flue gas flow in the respective spray arch 2 subsequent area. After passing through the third spray arch 2, the final cleaning takes place in this example under the action of the mist emanating from it. This is also illustrated in the illustration by a further loosening of the hatching. Depending on the intensity of the flue gas development and the effect of the fog, the number of spray arches 2 to be activated can be set as desired.

Claims

claims

1. Arrangement to secure the escape and rescue under smoke, heat and pollutant pollution from rooms with long escape routes, such as mines, underground traffic systems and. Ä., using mist-producing outlet devices,

characterized,

that the outlet devices (3) are attached along spray arches (2), which are arranged over the entire length of the room and / or its escape routes one behind the other and transversely to the escape direction, the clearance profile of the room and / or the escape routes.

2. Arrangement according to claim 1,

characterized by

that the outlet devices (3) are aligned in the direction of the prevailing air flow (6) in the rooms and / or escape routes.

3. Arrangement according to claim 1 and 2,

characterized by

that the spray cones (7) of the outlet devices (3) in the vicinity of the spray bend completely capture the cross-section of the room and / or escape route.

4. Arrangement according to claim 1 to 3,

characterized by

that the outlet devices (3) are pivotally attached to the spray arches (2).

5. Arrangement according to claim 1 to 3,

characterized by

that in each case two spray arches (2) are provided, each with outlet devices (3) spraying in opposite directions, the water supply to the spray arches being reversible.

6. Arrangement according to claim 1 to 5,

characterized by

that in the event of a fire, at least one spray bend (2) is activated in the direction of flow of the air after the source of the fire (5).

7. Arrangement according to claim 1 to 5,

characterized by

that in the event of a fire, at least one spray arc (2) is activated in the direction of flow of the air in front of the source of the fire (5).

Two pages of drawing