BE1021696B1 - SYSTEM AND METHOD FOR LIMITING EXPLOSION HAZARD - Google Patents

Abstract

System for limiting the risk of explosion in a closed space, comprising a storage vessel in which an extinguishing agent is stored, which storage vessel is provided with an outlet that can be connected to the closed space, the system further comprising at least one container in which an at least partially liquid propellant gas is stored under pressure; and for each container, an activator arranged to create a passage for fluid between the storage vessel and this container upon activation, such that upon activation of the activator, the propellant gas propagates along with the extinguishing agent in the enclosed space.

Description

System and method for limiting the risk of explosion

The present invention relates to a system and method for limiting, and in particular suppressing, the risk of explosion in an enclosed space.

Existing systems for suppressing the danger of explosion are typically based on the rapid injection of an extinguishing powder, typically sodium bicarbonate powder, into the sealed space to be protected. According to known systems, extinguishing powder is stored in a storage vessel together with a propellant gas, typically nitrogen gas, under high pressure (60 to 80 bar). For storing propellant gases under high pressure, pressure containers are required which must be regularly inspected. According to another known system, a gas generator is used which generates the necessary high pressure at the moment of activation of the gas generator. However, such a gas generator is expensive and complex to manufacture.

Embodiments of the present invention have the purpose of overcoming these disadvantages by providing a system and method that can more effectively limit or suppress an explosion hazard.

Embodiments of the present invention are based inter alia on the insight of the inventors that in the existing systems the extinguishing action is mainly based on the chemical and physical properties of the extinguishing powder and the interaction between the extinguishing powder and the explosion flame, and that a large part of the energy present in the propellant gas or generated gas is not optimally utilized.

An embodiment of a system according to the invention comprises a storage vessel in which an extinguishing agent is stored. The storage vessel is provided with an outlet which is intended to form a passage to the sealed space for fluid upon detection of the danger of explosion in the sealed space. The system further comprises at least one container in which an at least partially liquid propellant gas is stored under pressure; and for each container, an activator which is adapted to create a fluid passage between the storage vessel and this container after activation thereof, such that after activation of the activator the propellant gas is pushed into the closed space together with the extinguishing agent.

By using a propellant gas that is partially in a liquid phase in a container, when creating the fluid passage between the container and the storage vessel in which there is a lower pressure, typically about atmospheric pressure, the liquid propellant will flow out over a certain time and expand. Furthermore, the pressure in the container at the start of the outflow of the extinguishing powder to the sealed space is typically less high than in pressure vessels of prior art systems, and the pressure decreases less rapidly after activation than in prior art systems Technic. This makes it possible to achieve good explosion suppression with relatively small containers.

The propellant gas is preferably an extinguishing gas, even more preferably a cryogenic extinguishing gas, and for example one of the following is: carbon dioxide, nitrogen, argon, helium.

The extinguishing agent is preferably a powder, for example sodium bicarbonate, or a liquid, for example water.

More in particular, the invention makes it possible to work with one or more relatively small containers for which the legal requirements are less strict than for the pressure vessels used in known systems. For example, standard CO 2 containers with liquid CO2 of 20 to 200 grams may be suitable for use in embodiments of the invention.

The propellant gas is preferably such that the propellant gas expands upon activation of the activator and thereby absorbs ambient heat. The extinguishing agent will cool down due to expansion of liquefied gas in the container. In this way a cooling effect is created that can further contribute to suppressing the explosion in the enclosed space.

According to a further developed embodiment, the system comprises detection means which are adapted to detect explosions in the closed space, and a control connected to the detection means which is adapted to activate the activator upon detection of danger of explosion by the detection means.

According to a possible embodiment the system further comprises a gas generator and an additional activator which is adapted to activate the gas generator for injecting generated gas into the storage vessel, such that the extinguishing agent and the gas generated by the gas generator are pushed into the closed space . The control is then preferably arranged to also activate the additional activator upon detection of explosion hazard by the detection means. The gas generator is preferably adapted to generate a first pressure after activation of the additional activator that is higher in a first period of time than in a second subsequent period of time, and the propellant gas container is preferably adapted to generate a second pressure after activation. is lower than the first pressure in the first time period and higher than the first pressure in the second time period. It is noted that the gas generator used in systems of the invention can typically be much smaller than the gas generator used in prior art systems.

The invention further relates to a device comprising a closed space in the form of a silo, in which typically atmospheric pressure prevails, with a first inlet to which an embodiment of the system described above is connected. The closed space can further be provided with an outlet which is connected to a pipe in which a valve is included. The valve is movable from an open to a closed position when an explosion risk is detected. Such a valve is arranged to close the pipe very quickly, whereby the consequences of explosion propagation in pipes are limited or avoided. To that end, the control can be further adapted to control the valve in order to bring it into the closed position upon detection of danger of explosion by the detection means. The valve can be a mechanical or chemical valve, or a valve as described in the Belgian patent application with filing number BE 2012/0559 or BE 2012/0742 in the name of the Applicant.

The invention further relates to a method for limiting explosion risks in an enclosed space, comprising storing an extinguishing agent in a storage vessel with an outlet connected to the enclosed space; providing at least one container in which an at least partially liquid propellant gas is stored under pressure; and, upon detection of the danger of explosion, for each container, creating a fluid passage between the storage vessel and this container, such that the propellant gas is forced into the sealed space together with the extinguishing agent.

The propellant gas is preferably an extinguishing gas, and even more preferably CO 2, Ar, N, He, or a combination thereof. The extinguishing agent is preferably a powder or a liquid. The container with the at least partially liquid extinguishing gas can be selected as described above for the system.

According to a further embodiment, a gas generator can also be activated for injecting generated gas into the storage vessel, such that the extinguishing agent and the gas generated by the gas generator are pushed into the closed space. Preferably, a first pressure is generated with the gas generator that is higher in a first period than in a second subsequent period, and with the propellant container a second pressure is generated that is lower than the first pressure in the first period and higher than the first edition in the second period. As noted above, the gas generator required here may typically be much smaller than the gas generator used in prior art systems.

Advantageous embodiments of the system and the method are described in the claims. In addition, the method is preferably applied using an embodiment of a system as described above.

The invention will be further elucidated on the basis of a number of by no means limiting exemplary embodiments of the system and the method according to the invention with reference to the attached drawings, in which:

Figure 1 shows a schematic section of a first embodiment of a system according to the invention;

Figure 2 shows a schematic section of a second embodiment of a system according to the invention; and Figure 3 illustrates a schematic graph of pressure as a function of time for the second embodiment.

Figure 1 illustrates a first embodiment of an explosion suppression system according to the invention. The system comprises a storage vessel 10 in which an extinguishing agent B, typically an extinguishing powder, is stored. The storage vessel 10 is typically under approximately atmospheric pressure. The storage vessel 10 is provided with an outlet 11 which, after activation of the system, can communicate with an inlet of the closed volume, here a silo 50 which is typically also under approximately atmospheric pressure. The system further comprises a container 20 in which an at least partially liquid propellant gas is stored under pressure, for example liquid CO2 under a pressure of 10 to 20 bar, and an activator 21 which is adapted to create a passage for fluid between the storage vessel 10 and the container 20. This activator 21 is shown schematically and can be designed in many different ways, and can for instance be a pin which makes an opening in a wall or closure cap of the container 20, such that after activation of the activator Propellant gas D changes from the liquid state to the gaseous state, moves to the storage tank 10, and propagates together with the extinguishing agent B in the silo 50. The propellant gas flowing out of the container 20 can be partly in the liquid phase and partly in the gaseous phase.

The container 20 is preferably arranged such that, after activation of the activator, the propellant gas also causes a release of the extinguishing powder B, which is typically stored in the storage vessel 10 in a compacted state.

In the illustrated variant, the container is arranged outside of the storage vessel 10, but the container 20 could also be arranged in the storage vessel 10.

Although only one container 20 is shown in Figure 1, it is also possible to provide several containers 20 and associated activators 21, which, after activation, introduce propellant gas into the storage vessel 10. These activators 21 may or may not be activated simultaneously. These one or more containers 20 can, for example, be small CO2 bottles with a volume that is smaller than 0.5 liters, preferably smaller than 0.2 liters, in which liquid CO2 is stored, for example under a pressure of 10 to 20 bar, typically at a pressure of about 15 bar at room temperature.

In the illustrated embodiment, one explosion suppression system is provided in a side wall of the silo 50. The person skilled in the art understands that several such systems can be provided, which communicate with different openings in the wall of the silo 50.

A gas or dust explosion consists of a rapid combustion of a gas or dust and air mixture, and can be detected at a very early stage by detection means 30 known to those skilled in the art, which transmit a detection signal to a control 40. The control 40 is arranged to activator 21 for creating the fluid passage between the container 20 and the storage vessel 10. Between the storage vessel 10 and the silo 50, a barrier, for example a breaker plate, can be provided which is removed after activation of the system, for example by breaking the rupture plate due to the increased pressure in the storage vessel 10, to create a passage for extinguishing agent and propellant gas.

The effectiveness and efficiency of the explosion suppression can be considerably improved because the propellant gas itself can have a quenching effect, and because the propellant gas expands at the transition from the liquid to the gaseous phase and thereby absorbs heat and thus produces a cooling effect which further causes the explosion suppression. promotes. Both the extinguishing agent and the propellant gas are then at a relatively low temperature, which benefits the explosion suppression. In addition, relatively small, commercially available propellant gas containers can be used in which propellant gas is stored at least partially in liquid form, whereby the weight and the cost price of embodiments of systems according to the invention can be considerably lower in comparison with the known systems in which heavy pressure vessels are used.

Figure 2 illustrates a second embodiment of an explosion suppression system according to the invention. The system is analogous to the system of Figure 1, with the difference that a gas generator 60 with additional activator 61 is furthermore provided. The additional activator 61 is adapted to activate the gas generator 60 and to inject generated gas under high pressure into the storage vessel 10, such that the extinguishing agent B and the gas generated by the gas generator are pushed into the closed space 50. The control 40 is then further adapted to activate the additional activator 61 upon detection of danger of explosion by the detection means 30.

Figure 3 schematically illustrates a possible variation of the pressure as a function of time for a gas generator 60 and a container 20 according to an embodiment of the invention. The gas generator 60 is typically arranged to generate a first pressure P1 as a function of time after activation of the additional activator 61, which is higher in a first time period T1 than in a second subsequent time period T2, and the propellant 20 container is typically arranged to generate a second pressure P2 after activation which is lower than the first pressure P1 in the first time period T1 and higher than the first pressure in the second time period T2 after activation. It is further noted that the activators 21, 60 of the container 20 and the gas generator 60 may or may not be activated simultaneously. The graph of Figure 3 shows an example in which the activator 21 of the container 20 is activated a period ΔΤ after the activator 61 of the gas generator 60. As a result, the reaction time of the system may be shorter. According to a non-illustrated variant, the activator 61 of the gas generator 60 can be activated a period ΔΤ after the activator 21 of the container 20, in order to increase the extinguishing agent injection time.

The use of the gas generator in combination with a container makes it possible to make the system even faster or to extend the injection time. The gas generator 60 added in the variant of Figure 2 may typically be much smaller than the gas generators of known explosion suppression systems, since the gas generator 60 is only used here to give the system a faster start or to extend the extinguishing agent injection time, and most of the explosion suppression is done by efficiently using the propellant D stored in at least partially liquid form.

The invention is not limited to the exemplary embodiments described above, and those skilled in the art will understand that many modifications and variants are conceivable within the scope of the invention, which is only determined by the following claims.

Claims (17)

Conclusions System for limiting the risk of explosion in an enclosed space, comprising a storage vessel in which an extinguishing agent is stored, which storage vessel is provided with an outlet that can be connected to the closed space, characterized in that the system further comprises: - at least one container in which an at least partially liquid propellant gas is stored under pressure; and - for each container, an activator which is adapted to create a passage for fluid between the storage vessel and this container after activation thereof, such that after activation of the activator the propellant gas together with the extinguishing agent propagate in the closed space. System according to claim 1, characterized in that the propellant gas is an extinguishing gas, preferably a cryogenic extinguishing gas. A system according to any one of the preceding claims, characterized in that the drive tie is one of the following: carbon dioxide, nitrogen, argon, helium. A system according to any one of the preceding claims, characterized in that the extinguishing agent is a powder or a liquid. A system according to any one of the preceding claims, characterized in that the pressure and temperature in the storage vessel are such that the propellant gas expands upon activation of the activator. A system according to any one of the preceding claims, characterized in that the propellant gas is such that the propellant gas expands upon activation of the activator and thereby absorbs ambient heat when the pressure in the storage vessel and in the sealed space is approximately 1 atm, and the temperature is between -20 and 60 ° C. System as claimed in any of the foregoing claims, characterized in that the system further comprises: detection means which are adapted to detect the danger of explosion in the closed space; and a control connected to the detection means and adapted to activate the activator upon detection of danger of explosion by the detection means. 8. System as claimed in any of the foregoing claims, characterized in that the system further comprises a gas generator and an additional activator which is adapted to activate the gas generator for injecting generated gas into the storage vessel, such that the extinguishing agent and the the gas generator generated gas is driven into the confined space. 9. System as claimed in claims 7 and 8, characterized in that the control is further adapted to activate the additional activator upon detection of danger of explosion by the detection means. 10. System as claimed in claim 8 or 9, characterized in that the gas generator is adapted to generate a first pressure after activation of the additional activator that is higher in a first period of time than in a second subsequent period of time, and that the propellant container is adapted to generate a second pressure after activation that is lower than the first pressure in the first time period and higher than the first pressure in the second time period. 11. Device comprising a closed space in the form of a silo with a first inlet to which a system according to any one of claims 7-10 is connected. 12. Device as claimed in claim 11, characterized in that the silo has an outlet which is connected to a conduit in which a valve is accommodated, which valve is movable from an open to a closed position, wherein the control is further adapted to the valve to be driven in order to bring it into the closed position upon detection of danger of explosion by the detection means. A method for limiting explosion risks in a closed space, comprising storing an extinguishing agent in a storage vessel connected to the closed space, characterized in that the method further comprises: - providing at least one container in which a at least partially liquid propellant gas is stored under pressure; and - upon detection of the danger of explosion, creating a passage between the storage vessel and this container for each container, such that the propellant gas is pushed into the closed space together with the extinguishing agent. A method according to claim 13, characterized in that the propellant gas is an extinguishing gas, and is preferably one of the following: carbon dioxide, nitrogen, argon, helium. Method according to claim 13 or 14, characterized in that the extinguishing agent is a powder or a liquid. A method according to any one of claims 13-15, characterized in that further comprising activating a gas generator and injecting generated gas into the storage vessel, such that the extinguishing agent and the gas generated by the gas generator are pushed into the closed space . A method according to claim 16, characterized in that a first pressure is generated with the gas generator that is higher in a first period of time than in a second subsequent period of time, and that with the propellant container a second pressure is generated that is lower then the first pressure in the first period and higher than the first pressure in the second period.