NL9401480A - Method for extinguishing a fire. - Google Patents

Description

Method for extinguishing a fire

The invention relates to a method for extinguishing a fire by means of an extinguishing gas, wherein after detection of a fire, the extinguishing gas is supplied under high pressure to the room in which the fire occurs while simultaneously displacing air.

Such a method is applied in those cases where the use of liquid extinguishing agents is not possible or desirable, for example because of the expected damage as a result of the extinguishing liquid. As examples of such cases are mentioned storage spaces for precious objects such as art objects. The use of liquid extinguishing agents cannot be considered for electrical installations, and for certain installations in the chemical industry, etc.

The action of extinguishing gas is based either on the principle of a negative catalyst or on the principle of displacement. In the first case, the extinguishing gas contains halons. However, the use of halons is no longer permitted under recent environmental legislation, and as long as no replacement for halons is available, the displacement principle should therefore be used.

The latter principle is based on the fact that in almost all cases the ambient air exceeds 15? ” must contain oxygen to sustain itself. Air normally contains 21% oxygen; to a concentration of 12 ?! however, humans and animals are not harmed by a lower oxygen concentration. On the basis of these data, the extinguishing gas installations based on this principle are therefore designed in such a way that they can bring such an amount of extinguishing gas into the protected area in a very short time that the oxygen concentration there falls to a value between 12 ?! and 15 ?!

When extinguishing a fire according to the displacement principle, a relatively large amount of extinguishing gas is required. Although this quantity is introduced into the protected space via several feeders at the same time, very high flow velocities nevertheless occur at the inflow which can even approach the speed of sound. Also, with such a large influx, annoying side effects occur, such as entraining of ambient air, whereby strong air currents that have the character of a storm can be generated.

A further drawback of this known method, in particular of the high inflow velocity associated therewith, lies in the strong mixing that occurs between the air and the extinguishing gas. As a result, part of the extinguishing gas quickly disappears from the protected space, reducing the displacement effect.

In addition, the high air speed can initially ignite the fire. It can also disperse combustion products, burning substances, hazardous substances and / or infectious substances n the whirling up of dust, which is especially disadvantageous with vulnerable objects such as electronic equipment, works of art, etc. Such an influx is associated with high noise levels, so that communication becomes impossible and panic reactions may occur.

Roofs, walls, floors, windows and doors can also easily be overloaded by the large amounts of extinguishing gas. Furthermore, it is necessary to prevent the forced air from entering the adjacent space, which necessitates the presence of drains.

The object of the invention is therefore to improve the method described above in such a way that the drawbacks mentioned are avoided. This aim is achieved in that the extinguishing gas is supplied in a first step in a chamber bounded by a porous wall, and then in a second step is supplied via the porous wall to the fire to be extinguished.

The supply of the extinguishing gas to the protected space according to the invention thus has the advantage that, with a large extinguishing gas flow rate and a high supply pressure, the inflow rates remain limited. The porous wall offers such a large inflow surface that high local speeds can no longer occur. The noise production remains low.

A further advantage of supplying a large amount of extinguishing gas at a relatively low speed is the increased effectiveness thereof. The low inflow speeds lead to little mixing of air and extinguishing gas, as a result of which relatively little extinguishing gas is discharged from the room with the displaced air.

In this connection, the displaced air is preferably discharged in a place which is related to the ratio of the specific gravities of air and extinguishing gas. As a result of the only slight mixing, the extinguishing gas can propel the air out evenly. By now choosing the supply for extinguishing gas and the exhaust for displaced air, the desired extinguishing effect can already be obtained with relatively little extinguishing gas, since hardly any extinguishing gas is lost through the discharge.

According to a first possibility, an extinguishing gas is used in this context, the specific weight of which is higher than the specific weight of air, and the displaced air is discharged at a relatively high level.

3

According to an alternative, second possibility, an extinguishing gas is used whose specific gravity is lower than the specific gravity of air, and the displaced air is discharged at a relatively low level.

The invention also relates to a space provided with an extinguishing installation for carrying out the above-described method, comprising storage means for a stock of extinguishing gas under high pressure, a supply member connected to that stock, which opens into the space, and discharge means for discharging displaced air. from that space.

Again, according to a first possibility, an extinguishing gas can be used, the specific weight of which is higher than the specific weight of air, and the discharge means for discharging the displaced air in the space can be situated at a relatively high level.

According to a second possibility, an extinguishing gas can be used, the specific weight of which is less than the specific weight of air, and the discharge means for discharging the displaced air into the space are at a relatively low level.

The drains of the space can be provided with a seal that is breakable under the influence of overpressure in the space, for example a breakable membrane. Such a seal prevents any external influences, for example weather influences, from reaching the protected space in normal operation.

The invention furthermore relates to a supplying means for supplying extinguishing gas into a space as described above, comprising a chamber with an inlet opening for the extinguishing gas, and a porous wall for discharging extinguishing gas from the chamber.

The extinguishing gas supplied under high pressure expands in the chamber, the flow rate decreasing. The extinguishing gas then flows at moderate speed through the porous wall into the space to be protected. Another advantage is that the temperature drop that occurs during expansion remains relatively small, so that ice formation is omitted. Only a layer of frost deposits, which sublimates without drip phenomena, such as would occur with ice thawing.

Preferably, the inflow opening has an adjustable restriction for controlling the rate of extinguishing gas flow. When supplying the extinguishing gas via organs, the restrictions can be adjusted in such a way that a supply of the KI neflpae rtl + · is distributed evenly over all organs.

According to a preferred embodiment, the porous wall is cylindrical and is terminated at one end by an end bulkhead, while at the opposite end it has an end bulkhead with inflow opening.

Furthermore, the porous wall is preferably made of sintered stainless steel. Such a material is highly resistant to corrosion; there is therefore hardly any risk of constipation, even for a long time that requires preparedness. In addition, this material can be mechanically loaded without any problems. A further advantage is the predictable and easily reproducible porosity.

Incidentally, other sintered materials, such as sintered bronze, can also be used. The use of ceramic materials is also conceivable, provided that the mechanical loads allow this.

The feeder can also have two separate inflow openings with their own restriction. The double feed not only offers the possibility to mix different extinguishing gases and thus supply them simultaneously, but also makes it possible to inject water with the extinguishing gas. The atomized water will evaporate and expand quickly, while the impulse-free supply is maintained. As a result, both the air is quickly displaced, while heat is also extracted from the environment and the object to be extinguished as a result of the evaporation of the water.

The porous material feeder is also suitable for low-impulse atomization of a liquefied gas such as carbon dioxide, which leads to much more effective oxygen displacement and cooling. The latter application is also suitable as water-saving cooling in production processes.

The invention will be explained in more detail below with reference to an exemplary embodiment shown in the figures.

Fig. 1 shows a vertical section through a space with an extinguishing gas installation according to the invention.

Fig. 2 shows a section through the feeder according to the invention.

The space 1 shown in figure 1, in which an object which is not further specified to be protected against fire is located, is provided with two supply members 2 according to the invention for extinguishing gas. These feed members are connected in known manner via pipework 3 and valve 4 to a container 5. In this container 5 a large amount of extinguishing gas is stored under high pressure.

As soon as fire is detected in the space 1, for instance via detection means known per se, not shown, the valve k is opened in a manner which is also not shown, after which the extinguishing gas flows under high pressure and speed to the supply members 2.

As shown in figure 2, these feed members 2 consist of a chamber 6, surrounded by a porous, cylindrical wall 7. This porous, cylindrical wall can for instance consist of stainless sintered steel. On one end of the chamber 6 there is a wall 8, on the other side a wall 9 with an inlet 10. For this inlet 10 there is a restriction 11, which is adjustable in such a way that the same flow rate can be supplied via both inlet members 2 obtained.

The extinguishing gas expands in chamber 6, reducing pressure and speed. The extinguishing gas then flows into room 1 at a moderate speed.

In the illustrated exemplary embodiment, the extinguishing gas has a specific weight which is higher than the air initially present in the space 1. In addition, since the extinguishing gas flows in at a moderate speed, as a result of which mixing with the air hardly occurs, the extinguishing gas will initially accumulate at a low level 12 in space 1. The extinguishing gas front 13 expels the air present in space 1 in front of it, such that the air can flow evenly through the drains provided in space 1. The air flow is indicated by the arrows 15 ·

The advantage of this method is that hardly any extinguishing gas is lost via the drains 14, such that an extinguishing effect can be achieved with minimal amounts of extinguishing gas. A further advantage is that hardly high flow velocities occur in space 1, as a result of which the objects located there are spared and no spread of dangerous or infectious substances will occur.

Claims (14)

A method for extinguishing a fire by means of an extinguishing gas, wherein after detection of a fire, the extinguishing gas is supplied under high pressure to the space in which the fire occurs with simultaneous displacement of air, characterized in that the extinguishing gas in a first step is fed into a chamber bounded by a porous wall, and then supplied in a second step through the porous wall to the fire to be extinguished. The method of claim 1, wherein the displaced air is exhausted at a location associated with the ratio of the specific gravities of air and extinguishing gas. A method according to claim 2, wherein an extinguishing gas is used whose specific weight is higher than the specific weight of air, and the displaced air is discharged at a relatively high level. A method according to claim 2, wherein an extinguishing gas is used whose specific gravity is less than the specific gravity of air, and the displaced air is discharged at a relatively low level. Space provided with an extinguishing installation for carrying out the method according to one of the preceding claims, comprising storage means for a stock of extinguishing gas under high pressure, a supply member connected to said stock, which opens into the space, and discharge means for expelling displaced air from that space. Space according to claim 5, wherein an extinguishing gas is used, the specific weight of which is higher than the specific weight of air, and the exhaust means for extracting the displaced air in the space are at a relatively high level. Space according to claim 5, wherein an extinguishing gas is used whose specific weight is less than the specific weight of air, and the exhaust means for extracting the displaced air in the space are at a relatively low level. Room according to claim 5> 6 or 7, wherein each drain is provided with a seal that can be broken in the room under the influence of overpressure. The space of claim 8, wherein the seal comprises at least a rupturable membrane. 10. Supply means for supplying extinguishing gas into a space according to any one of claims 5-9 comprising a chamber with an inlet opening for the extinguishing gas, and a porous wall for discharging extinguishing gas from the chamber. Supply member according to claim 10, wherein the inflow opening has an adjustable restriction for controlling the flow rate of the extinguishing gas stream. Feeder as claimed in claim 10 or 11, wherein the porous wall is cylindrical, is terminated at one end by an end bulkhead, and has an end bulkhead with inflow opening at the opposite end. Supply member according to claim 12, wherein the inflow opening has an adjustable restriction. 1 * 1. Feeder as claimed in any of the claims 10-13, wherein the porous wall consists of sintered stainless steel. Supply member according to any one of claims 10-14, wherein two separate inflow openings are provided with their own restriction.