NL2018996B1 - Method for extinguishing a fire with extinguishing medium at a location, in particular with carbon dioxide - Google Patents

Abstract

The present invention relates to a method for extinguishing a fire with extinguishing medium at a location, in particular carbon dioxide, nitrogen or a mixture thereof, comprising the steps of providing liquid medium and converting the liquid medium to gaseous medium by means of evaporating the liquid medium. The method further comprises the step of heating the gaseous medium to substantially above 0 ° C. After heating, the heated gaseous medium is used to extinguish the fire. In one embodiment, the method comprises providing a foaming agent, combining the foaming agent and the gaseous medium to produce extinguishing medium containing foam, in particular carbon dioxide gas containing foam, and extinguishing the foam with heated gaseous medium. fire. The invention also relates to a system for use in the method.

Description

Brief description: Method for extinguishing a fire at a location with extinguishing medium, in particular with carbon dioxide

Description

The present invention relates to a method for extinguishing a fire with extinguishing medium at a location, in particular carbon dioxide.

Fire fighting is the oldest and most important task of the fire department. The purpose of fire fighting is of course to extinguish a fire, but also to rescue and evacuate victims, prevent damage or prevent nuisance.

Different types of fires can be distinguished, each type has certain characteristics that influence the method of fire fighting. For example, a large distinction can be made based on indoor fires and outdoor fires.

Indoor fires involve a fire in an enclosed space, usually a building, such as a home. In such environments there is often a lot of combustible material present, and because of the enclosed space it will become very hot, up to more than 600 ° C. In high-rise houses, for example in apartment buildings, additional fire-fighting problems occur. If the fire takes place at a higher altitude, above 30 meters, then combat from the outside of the building is no longer possible because a car ladder or aerial platform is not high enough for this. If a building is higher than 70 meters, the building must have a special fire extinguishing water supply because the required pressure becomes too high for the hoses and the pump in the tanker sprayer.

Outdoor fires involve a fire in a free space. The advantage of this is that little heat remains, the disadvantage is that a lot of oxygen is added to the fire due to wind or other air displacement.

An industrial fire can involve both an indoor fire and an outdoor fire. Such fires are often very varied in nature and scope. Industrial buildings are not always clear and often quite large. Fire protection has been considered in most industrial buildings, and at least small extinguishing agents such as fire hoses or fire extinguishers are present. Some companies have their own company fire brigade. Due to the possible presence of all kinds of different substances and materials, many different hazards can arise, such as an explosion, BLEVE ("boiling liquid expanding vapor explosion"), rapid fire spread or the formation of toxic gases.

There are various extinguishing methods. The extinguishing agent can for instance be liquid, but can also be powdered or gaseous. Commonly used extinguishing agents are water, powder, foam, and carbon dioxide (CO2). With such an extinguisher, liquid CO2 is sprayed from a holder and a hose, via an expansion tube or snow tube at the end of the tube, to the fire. The extinguishing property is that the CCti cloud displaces oxygen, causing the fire to die out. This makes this extinguisher particularly suitable for use indoors and / or lockable spaces.

The present invention has for its object to provide an improved method for extinguishing a fire.

With this aim in mind, the present invention provides a method for extinguishing a fire with extinguishing medium at a location, in particular carbon dioxide, nitrogen and / or a mixture thereof, comprising the steps of providing liquid medium; converting the liquid medium to gaseous medium by evaporating the liquid medium; heating the gaseous medium to substantially above 0 ° C; and extinguishing the fire with the heated gaseous medium.

In the present specification, heated gaseous extinguishing medium is particularly understood to mean a gas or gas mixture containing carbon dioxide (CO2), nitrogen (N2) or a mixture thereof. In one embodiment, the gas comprises carbon dioxide (CO2) and nitrogen (N2). A characteristic of gaseous CO2 is that when it is released it is heavier than air, so it drops to the ground. This is an advantage with fires that are close to the ground. Nitrogen is no heavier than air, and therefore a full space can be achieved.

By applying, for example, CO2 in a space, the space will be filled with gaseous CO2. this also lowers the oxygen content in the room so that no further fire can occur. By introducing gaseous CO2, an overpressure is also created and an oxygen-rich mixture is released. This means that fresh oxygen can no longer reach the fire and the fire will die out. In contrast to liquid CO2, where very cold liquid is injected into the room and damage to objects can occur (freezing), the use of heated gaseous CO2 does not cause this disadvantage, since the gaseous CO2 has already been brought up to temperature in advance. Moreover, the fact that gaseous CO2 is introduced ensures that you can introduce it at a lower pressure. This is safer and more reliable, but it also increases the range with which the extinguishing agent can be introduced into the room. This makes it even possible to extinguish a fire without the need for firefighters to enter the building. There is also the risk of liquid introduction that if you stop, the pressure in the supply hose will decrease to less than 6 bar and that the liquid CO2 will pass in a solid phase, a frozen state. As a result, frozen snakes, you can no longer restart. With gaseous CO2 this danger is not present and people can stop and start as many times as they want. This makes it easier for you to keep a fire under control by adding CO2 several times to replenish the CO2 lost in the room due to leaks.

The step of extinguishing the fire with the heated gaseous medium takes place after the conversion of liquid extinguishing medium. The liquid medium is converted at a distance from the fire. In one embodiment, the conversion takes place in a substantially closed system. Unlike the state of the art, where, for example, liquid CO2 is supplied to a fire, the method according to the present invention precisely comprises the targeted supply of gaseous medium, such as CO2, to the fire.

In one embodiment, the method comprises the further steps of providing a foaming agent; bringing the foaming agent and the gaseous medium together to produce extinguishing medium-containing foam, in particular carbon dioxide-gas-containing foam; and extinguishing the fire with the foam with heated gaseous medium.

The foam with heated gaseous medium can be a foam comprising a gas mixture. In one embodiment, the gas mixture comprises the heated gaseous carbon dioxide and / or nitrogen.

By applying foam, the fire can be covered with a layer without oxygen. The foam surrounds the fire, like a blanket. In an advantageous embodiment, the foam contains gaseous CO2. The gaseous CO2 prevents new oxygen from reaching the combustion, causing the fire to die out. This is advantageous, for example, in the event of a fire on objects, or even in the event of external fires.

The advantage is also that the foam can be sprayed in a very targeted way, and that the user receives some feedback about where he is extinguishing.

The great advantage of foam, however, is that in situations where flammable material could ignite due to a high temperature, it can be covered by a layer of foam to extract oxygen. If a foam bubble bursts, however, unlike foam according to the prior art, no oxygen is released but extinguishing medium, in particular, for example, CO2. This will result in a reduction to the risk of ignition. The foam is also applicable to liquid fires.

In one embodiment, the foaming agent is a soap agent. Liquid CO2 is converted by the device into a gaseous phase. A bubble can then be created, for example with the aid of a foam lance. In general, this is similar to the process as with a "bubble-blowing children's toy". A mixture of a soap / detergent and water is provided. The gas CO2 is added to the soap mixture via a foam nozzle. This is where the gas-filled bubble arises. A gas bubble always tends to break, because gravity causes the soap to run from the top of the bubble to the bottom, which eventually bursts the bubble. This releases the CO2, or more generally the gaseous extinguishing agent, and is stored between the other bubbles. It is possible to let the foam come out of the foam nozzles close to the fire, but it is also possible to allow this foam to come out of the foam nozzle remotely and due to a continuous production of foam it moves like a wave to forward and can travel a long distance.

If a mixture with a high nitrogen content is used for the foam, this can be applied over the fire and if a bubble bursts then no oxygen is added to the fire but a nitrogen-containing mixture. With large quantities of gas released, nitrogen is always a gas that, due to an 80% presence in the breathing air, is less likely to lead to the danger of suffocation for rescuers.

Many buildings already contain systems that are connected to various rooms, such as ventilation systems (extraction at the office, air conditioning etc.). When these systems are switched off, the pipework can be used directly as a rapid distributor of the heated gaseous extinguishing medium, such as CO2, in the building. In one embodiment the method thus comprises supplying the heated gaseous extinguishing medium, such as CO2, N2 or a mixture thereof, via a pipe system from a building to a fire.

In one aspect, the present invention provides a system for use in the method of any one of the preceding claims, comprising a container for liquid extinguishing medium; an evaporator device for converting the liquid medium into gaseous medium; a conditioning unit for bringing the gaseous medium to a desired temperature; as well as outflow means connected to the holder and adapted to discharge heated gaseous medium from the system for extinguishing the fire.

Advantages of such a system have already been further elucidated with reference to the method according to the present invention.

In one embodiment the system comprises a container for foaming agents; and a foam device for the production of extinguishing medium-containing foam. The extinguishing medium-containing foam may in particular be carbon dioxide-gas-containing foam, or nitrogen-gas-containing foam, or a mixture thereof.

In one embodiment the system comprises a heat exchanger, in particular wherein the heat exchanger forms part of the evaporator device and / or the conditioning unit.

In an efficient embodiment, the heat exchanger is of the "Shell and Plate" type.

In one embodiment, use is made of CO2. CO2 is very suitable for complex fires, such as on an object consisting of several rooms, where smoke development means that rooms can no longer be accessed by the emergency services. In such a case, the state of the art attempts to extinguish the fire from outside by adding water. This is a long-term process in which less effectiveness puts more emphasis on preserving surrounding objects. By introducing CO2 into the object and distributing the gas homogeneously through the laws of nature, a fire is extinguished from within.

The invention will be explained below with reference to the accompanying figures, in which some embodiments of the present invention are explained. In the figures:

FIG. 1 - a schematic view of a system for performing the method according to the present invention;

FIG. 2 - a schematic view of an alternative system for carrying out the method according to the present invention;

FIG. 3 - a schematic view of a further alternative system for carrying out the method according to the present invention;

FIG. 4 - a schematic overview of details of the system;

FIG. 5 - a schematic overview of details of an evaporator according to the present invention.

It is noted that in the example below the invention is generally explained on the basis of extinguishing medium, and in particular in an example carbon dioxide. However, it is also possible to use nitrogen in the extinguishing medium. Alternatively, or additionally, a mixture of carbon dioxide and nitrogen can be used as an extinguishing medium.

FIG. 1 shows very schematically a side view of a system 1 for extinguishing a fire with carbon dioxide. The system 1 comprises a tanker truck 2. The tanker truck 2 comprises a movable frame 21 and a holder 22 for holding liquid medium. A connection 23 is provided on the tanker truck 2, via which liquid medium can be carried out of the holder 22. The liquid medium then has a temperature of approximately -25 ° C.

The system 1 also comprises an evaporator device 3 which is adapted for converting liquid medium into gaseous medium. In the embodiment shown, the evaporator device 3 comprises a movable frame 31 on which an evaporator 32 is provided. In this evaporator 32 parts are provided for converting the liquid medium to the gaseous medium, as will be explained later with reference to Figs. 5. The evaporator device also includes a conditioning unit (not shown) for bringing the gaseous medium to a desired temperature. In FIG. 1 shows that there is a supply 33 for the liquid medium and a drain 34 for the gaseous medium. The supply 33 is connected via a first conduit 6 to the tank truck 2, such that cold liquid medium can be supplied to the evaporator device 3. A second conduit 7 is connected to the outlet 34 of the evaporator device 3, which in the interior of the container 4, and is provided with an outflow means 8, in the form of a nozzle 8, which are adapted for supplying heated gaseous medium to the system for extinguishing the fire. In practice, instead of a single nozzle 8, use can be made of a distribution system with a number of nozzles, so that gaseous medium can be supplied to the fire at a number of places. It will therefore be clear to those skilled in the art that the invention is not limited to the use of a single nozzle.

With the in FIG. The system 1 shown in Fig. 1 can be extinguished in the following manner. The tanker truck 2 and the evaporator device 3 are provided, and placed in the vicinity of the fire (not shown). The tanker truck 2 is connected via conduit 6 to the evaporator device 3, by connecting the conduit 6 to the outlet 23 and the inlet 33. The conduit 7 is connected to the outlet 34 of the evaporator device 3. The evaporator device 3 can then operate in which cold liquid extinguishing medium is supplied to the evaporator device 3, is converted on site into gaseous extinguishing medium, and subsequently supplied to the fire as gaseous extinguishing medium. The evaporator device 3 is thereby used to condition, in particular to heat, the converted extinguishing medium, in particular the converted carbon dioxide, to a temperature which is substantially above zero degrees Celsius, such that freezing damage to adjacent objects or to the burning fire existing materials, etc., is prevented.

FIG. 2 shows an alternative system 1 that substantially corresponds to the system of FIG. 1, but substantially different therefrom, in that the evaporator device 3 here is not provided with a movable frame 31, as in FIG. 1 is the case. A movable frame 31 as in FIG. 1 is advantageous in itself, because then the evaporator 32 can be placed relatively autonomously at a desired location. The evaporator device 3 as shown in FIG. 2, however, forms a separate unit, which actually consists of the evaporator 32 with the inlet 33 and the outlet 34. This makes the evaporator 32 less complex and less expensive. This separate evaporator 32 can, if desired, be brought by a suitable vehicle to the location of the container 4, and be placed. Optionally, such a device can be placed at a risky location on, for example, an industrial site. For an explanation of the evaporator 32, reference is made to the description of FIG. 5.

FIG. 3 shows a further alternative system 101, in which use is made of an evaporator device 103 for supplying gaseous medium to a fire 44 present in a space 43. The evaporator device 103 comprises a movable frame 121 on which a liquid medium holder 122 is placed. The evaporator 132 is also placed on the frame 121. The outlet 123 of the container 122 is connected to the inlet 133 of the evaporator 132; the outlet 134 of the evaporator 132 is led via conduit 7 to the space 43. In fact, an integrated movable liquid medium holder with evaporator 132 for producing gaseous medium is provided in this embodiment. It is not immediately shown that there is also a conditioning unit in the evaporator for heating the gaseous CO2. Incidentally, the frame 121 can also be omitted in this embodiment, just as in the embodiment of FIG. 2.

It will thus be clear to those skilled in the art that the use of a displaceable frame 21, 31, 121 is in itself advantageous, but that the invention is not limited to its use. Embodiments of the arrangement 1, 101 in which no use is made of one or more frames are also conceivable.

FIG. 4 shows a schematic overview of an embodiment of conversion unit 3, with which a gas mixture of carbon dioxide and nitrogen can be made. The conversion unit 3 has a feed for liquid medium 33a (shown below in Fig. 4), and a feed for nitrogen 33b (top in Fig. 4). The liquid medium is converted to gaseous medium in an evaporator 9, and is then stored in a carbon dioxide buffer container 82. The nitrogen is stored in a buffer container 81 for nitrogen. Upon activation of the system, buffered carbon dioxide from the buffer container 82 can then be mixed with buffered nitrogen from the buffer container 81, after which the mixture can be supplied to the outflow means 8.

In the conversion unit 3 of FIG. 4, a foaming device may also be included. A foaming device is generally known per se, for example in the form of a foam lance, and the person skilled in the art will be able to use a suitable foaming device.

FIG. 5 shows a schematic overview of the most important parts of the device shown in FIG. 1, 2 and 3. Evaporator device 3. Generally, this evaporator device 3 has a liquid medium inlet 33 and a gaseous medium outlet 34. These are normally located on the outside of the evaporator 32, 132, the remaining parts shown in FIG. 4 are then located on an inside of the evaporator 32, 132.

FIG. 5 shows that the evaporator device 3 comprises an energy source 51, in particular a heating boiler with a power that is between 100 kW and 5000 kW. Via lines 61, 62, heated fluid, in particular water, can be transported by the energy source 51 from and to a buffer vessel 52. The buffer vessel 52 is adapted to keep the fluid in stock at a temperature between 20 ° C and 95 ° C. Between the boiler 51 and the buffer tank 52, an expansion tank 57 is provided, which is connected via line 67.

From the buffer vessel there is a first cycle (left side Fig. 5) which runs via line 65 and a pump unit 56 placed therein to a first heat-exchanging section 53, and returns via line 66 to the buffer vessel 52. The first heat-exchanging section 53 is arranged to liquid medium of -25 ° C (i.e. gaseous), and can therefore be considered as an evaporator unit 53. To this end, the fluid in line 65 is heated to a temperature of approximately between 20 ° C and 95 ° C supplied to the first heat exchanging portion 53. After heating up the carbon dioxide, and converting to gaseous medium, the fluid has cooled, for example to about 1 ° C, and will be returned via line 66 to the buffer vessel 52. By applying the energy source 51, in this case the heating boiler 51, the buffer vessel 52 can be brought back to the desired supply temperature and kept there. The power of the energy source 51 is thereby set such that during use sufficient energy can be supplied to the fluid to keep the buffer vessel at the desired temperature and to allow the conversion of liquid medium to gaseous medium to continue during continuous use of the evaporator unit.

In summary, it can be stated that the first cycle with the first heat-exchanging portion 53 is adapted for converting liquid medium into gaseous medium.

The evaporator device 3 further comprises a second circuit (right-hand side Fig. 4) which, via line 63 and a pump unit 55, supplies fluid from the buffer vessel 52 to a second heat-exchanging section 54, and returns the fluid via line 64 to the buffer vessel 52. The second heat-exchanging portion 54 is adapted to heat the gaseous medium to a desired temperature, such as, for example, about 20 ° C. The second heat exchanging portion 54 can therefore be considered as a conditioning unit for bringing the gaseous medium to a desired temperature.

In the embodiment shown in FIG. 5, the first heat exchange part 53 and the second heat exchange part 54 are formed by a heat exchanger. The first heat exchanging portion 53 and the second heat exchanging portion 54 are placed one behind the other and coupled to each other. The portions 53, 54 may be arranged to operate separately, but may also be arranged to support each other. In a special embodiment this can be a heat-exchanger of the "Shell-and-plate" type. Other heat exchangers are of course also conceivable.

The evaporator device 3 may comprise a control unit known per se to the person skilled in the art, such that the power of the energy source, the temperature of the buffer vessel, and the fluid flows through the first cycle and the second cycle are controlled automatically. Furthermore, valves and pump units, optionally supplemented with buffer holders for storing gaseous CO2, can be provided as desired. Those skilled in the art will be able to assemble and apply such a system.

The evaporator device according to the present invention allows a constant capacity of tons of extinguishing medium to be used, in particular tons of CO2 per hour. No extinguishing damage can occur, for example to electronic equipment in the building whose fire must be extinguished.

The applicant has also found that the consumption of gaseous CO2 is lower than that of liquid CO2 that is introduced into a space to evaporate from there. According to the applicant, the cause of this lies in the fact that, from a molecular point of view, a gas form is CO2 more voluminous than a liquid form. As a result, a constant volume percentage can be achieved with less kg of CO2.

Furthermore, according to the present invention, a low-oxygen gas, in particular gaseous extinguishing medium such as gaseous carbon dioxide or a carbon dioxide-containing gas mixture, is supplied to the fire. This includes in any case the direct introduction of a carbon dioxide-containing mixture into a gaseous phase. The use of any auxiliary substances is also included. It is thus conceivable that the gaseous medium is used in the manufacture of a foam, wherein the foam is subsequently introduced into the space. This makes it easy to cover the fire with a layer of foam, so that it is surrounded by gaseous CO2.

Incidentally, it is noted that the invention described above can in principle be applied with a low-oxygen gas mixture, that is to say a gas mixture in which substantially no oxygen is present, but for example nitrogen and / or carbon dioxide.

The requested protection is determined by the appended claims.

Claims (7)

A method for extinguishing a fire with an extinguishing medium at a location, comprising the steps of: - providing liquid medium comprising at least carbon dioxide, nitrogen, and / or a mixture thereof; - converting the liquid medium to gaseous medium by evaporating the liquid medium; - heating the gaseous medium to substantially above 0 ° C; - extinguishing the fire with the heated gaseous medium. Method according to claim 1, comprising the further steps of: - providing a foaming agent; - bringing together the foaming agent and the gaseous medium for producing extinguishing medium-containing foam; - extinguishing the fire with the foam with heated gaseous medium. The method of claim 2, wherein the foaming agent is a soap agent. System for use in the method according to one of the preceding claims, comprising: - a container for liquid extinguishing medium; - an evaporator device for converting the liquid medium into gaseous medium; - a conditioning unit for bringing the gaseous medium to a desired temperature; and - outflow means connected to the holder and adapted to discharge heated gaseous medium from the system for extinguishing the fire. System as claimed in claim 4, comprising: - a container for foaming agents; and - a foam device for the production of extinguishing medium-containing foam. 6. System as claimed in claim 4 or 5, wherein the system comprises a heat exchanger, in particular wherein the heat exchanger forms part of the evaporator device and / or the conditioning unit. The system of claims 4-6, wherein the heat exchanger is of the "Shell and Plate" type.