INSTALLED FIRE EXTINGUISHING APPARATUS, ESPECIALLY FOR THE FIRE PROTECTION OF USE LOCATIONS COMPRISING ENDANGERED STRUCTURES SEPARATED FROM EACH OTHER BY SPACES

Abstract

The invention relates to an installed fire extinguishing apparatus, which has a pressure-resistant storage body (10) with an internal space (11) for accommodating the fire extinguishing material composition (1) transportable in a pipeline, at least one dispersion device (3), and at least one transport pipeline (20) which is suitable for transporting the fire extinguishing material composition (1) from the internal space (11) of the storage body (10) to the dispersion device (3) arranged at the use location (2), where the storage body (10) is formed by a long pipeline (C) or a pipeline (C) that returns on itself that has a straight line main axis (T) or a main axis (T) of another shape, a trigger part-unit (4) is installed in the transport pipeline (20), and the storage body (10) is connected to a filling fitting (6) serving for filling the fire extinguishing material composition (1) or the components of the fire extinguishing material composition (1) into the internal space (11) of the storage body (10), the storage body (10) is coupled with at least one gas vessel (30), the internal space (31) of the gas vessel (30) is connected to the internal space (11) of the storage body (10) with a connection line (32) that permits the flow of medium, the gas vessel (30) and/or the storage body (10) and/or the connection line (32) has a valve (33) that influences the flow of medium between the gas vessel (30) and the storage body (10). The characteristic feature of the invention is that when the fire extinguishing apparatus is in a condition ready for use, more than 94% of the internal space (11) of the storage body (10) is filled with fire extinguishing material composition (1), where the composition (1) has a liquid and a gaseous component, and at least a part of the external surface (12) of the storage body (10) is surrounded by a material that reduces temperature fluctuations (5).

Claims

1. Installed fire extinguishing apparatus, especially for the fire protection of use locations comprising endangered structures separated from each other by spaces, which has a pressure-resistant storage body (10) with an internal space (11) for accommodating the fire extinguishing material composition (1) transportable in a pipeline, at least one dispersion device (3) for applying the fire extinguishing material composition (1), and at least one transport pipeline (20) connected to the internal space (11) of the storage body (10) and suitable for transporting the fire extinguishing material composition (1) from the internal space (11) of the storage body (10) to the dispersion device (3) arranged at the use location (2), where the storage body (10) is formed by a long pipeline (C) or a pipeline (C) that returns on itself that has a straight line main axis (T) or a main axis (T) of another shape, a trigger part-unit (4) is installed in the transport pipeline (20), and the storage body (10) is connected to a filling fitting (6) serving for filling the fire extinguishing material composition (1) or the components of the fire extinguishing material composition (1) into the internal space (11) of the storage body (10), the storage body (10) is coupled with at least one gas vessel (30), the internal space (31) of the gas vessel (30) is connected to the internal space (11) of the storage body (10) with a connection line (32) that permits the flow of medium, the gas vessel (30) and/or the storage body (10) and/or the connection line (32) has a valve (33) that influences the flow of medium between the gas vessel (30) and the storage body (10), characterised by that when the fire extinguishing apparatus is in a condition ready for use, more than 94% of the internal space (11) of the storage body (10) is filled with fire extinguishing material composition (1), where the composition (1) has a liquid and a gaseous component, and at least a part of the external surface (12) of the storage body (10) is surrounded by a material that reduces temperature fluctuations (5).

2. Installed fire extinguishing apparatus according to claim 1, characterised by that at least one lower point (14a) of the lower delimiting line (14) of the internal surface (13) delimiting the internal space (11) of the storage body (10) is located under the other points forming the section surrounding the lower delimiting line (14) as compared to the horizontal, and at least one upper point (15a) of the upper delimiting line (15) of the internal surface (13) delimiting the internal space (11) of the storage body (10) is located above the other points forming the section surrounding the upper delimiting line (15).

3. Installed fire extinguishing apparatus according to claim 2, characterised by that the connection line (32) of the gas vessel (30) is connected to the internal space (11) of the storage body (10) at at least one position of the storage body (10) established as a pipeline (C).

4. Installed fire extinguishing apparatus according to claim 2 or 3, characterised by that a purge fitting (40) is connected to the internal space (11) of the storage body (10) at at least one upper point (15a) of the storage body (10) established as a pipeline (C) or in its environment.

5. Installed fire extinguishing apparatus according to any of claims 2 to 4, characterised by that the storage body (10) established as a pipeline (C) is divided into at least two pipeline sections (C1, C2), and sectioning valves (50) influencing the flow of medium between the pipeline sections (C1, C2) are installed between two neighbouring pipeline sections (C1, C2).

6. Installed fire extinguishing apparatus according to claim 1, characterised by that the storage body (10) is set up as a vessel.

7. Installed fire extinguishing apparatus according to any of claims 1 to 6, characterised by that the storage body (10) is entirely recessed under the ground surface, and so the material layer that reduces temperature fluctuations (5) surrounding the external surface (12) of the storage body (10) is the accommodating earth itself.

8. Installed fire extinguishing apparatus according to any of claims 1 to 6, characterised by that on at least a part of the storage body (10) the material layer reducing temperature fluctuations (5) is heat insulation or shield.

9. Installed fire extinguishing apparatus according to any of claims 1 to 6, characterised by that on at least a part of the storage body (10) the material layer that reduces temperature fluctuations (5) is a layer of paint at least partially reflecting solar radiation.

10. Installed fire extinguishing apparatus according to any of claims 1 to 9, characterised by that the gas vessel (30) is established as a high-pressure bottle.

11. Installed fire extinguishing apparatus according to any of claims 1 to 10, characterised by that the transport pipeline (20) is connected to the lower side of the storage body (10).

12. Installed fire extinguishing apparatus according to claim 11, characterised by that the transport pipeline (20) is connected to the internal space (11) of the storage body (10) in the lower delimiting line (14) of the internal surface (13) delimiting the internal space (11) of the storage body (10) or in the vicinity of the lower delimiting line (14).

13. Installed fire extinguishing apparatus according to any of claims 1 to 12, characterised by that at least one abnormality-detecting body (60) is located at the use location (2).

14. Installed fire extinguishing apparatus according to claim 13, characterised by that the abnormality-detecting body (60) has a fire detector.

15. Installed fire extinguishing apparatus according to any of claims 1 to 14, characterised by that the use location (2) is a structure at least periodically accommodating combustible material.

Description

[0027] Further details of the installed fire extinguishing apparatus according to the invention will be explained by way of embodiments with reference to figures. Wherein

[0028] FIG. 1 depicts a top view of a schematic image of a version of the apparatus according to the invention,

[0029] FIG. 2 depicts a stepped cross-section of the apparatus according to FIG. 1, taken by the line II-II.

[0030] A version of the installed fire extinguishing apparatus according to the invention can be seen in FIG. 1 that can be used to good effect in the case of tank depots storing combustible, flammable and explosive materials, such as crude oil refineries, pharmaceutical plants and chemical industry facilities.

[0031] It may be observed that the pipeline “C” running between the individual use locations 2 forms the storage body 10 suitable for accommodating the fire extinguishing material composition 1. In the case of the present version the pipeline “C” forming the storage body 10 is established as a ring returning onto itself. Here the pipeline “C” forming the storage body 10 itself is divided into a pipeline section “C1” and a pipeline section “C2” with the help of the sectioning valves 50. Depending on the status of the sectioning valves 50 the pipeline section “C1” and the pipeline section “C2” can be connected to each other or isolated from each other.

[0032] The other great advantage of the positioning of the sectioning valves 50 is that in the case of physical damage to a given pipeline section “C1”, “C2”, the operation of the undamaged pipe sections can be continued by closing the sectioning valves 50, and in the case of a pipeline “C” arrangement where it returns onto itself, the entire remaining volume may be used.

[0033] The storage body 10 has at least one filling fitting 6 the task of which is to fill the internal space 11 of the storage body 10 delimited by its internal surface 13 with fire extinguishing material composition 1, and optionally the circulation of the fire extinguishing material composition 1 already filled into the internal space 11 of other pipeline sections by making it flow between the filling fittings 6.

[0034] The internal space 11 of the storage body 10 is connected to transport pipelines 20 leading to the use locations 2. Here trigger part-units 4 are installed in the transport pipelines 20, the task of which is in the case of any abnormality, e.g. in the case of a fire occurring at a use location 2, to make it possible for the fire extinguishing material composition 1 to pass from the internal space 11 of the storage body 10 via the transport pipeline 20 to the use location 2. In the interest of this the dispersion device 3 is connected to the end of the transport pipeline 20 at the use location 2, which dispersion device 3 disperses the fire extinguishing material composition 1 arriving on the transport pipeline 20 at the use location 2 so that the fire occurring there can be extinguished.

[0035] Also, in the interest of the monitoring personnel or the control centre of the fire extinguishing apparatus being informed of an emergency, e.g. fire, occurring at the use location 2, optionally even from a larger distance, the use location 2 has an abnormality detecting body 60. The abnormality detecting body 60 may be a fire detector, smoke detector or any device that is capable of detecting a significant physical and/or chemical change at the given use location 2, and sending a signal about this change to the location where a decision is made about the intervention.

[0036] FIG. 1 also well illustrates that the pipeline “C” of the storage body 10 is connected to the gas vessel 30 via the connection line 32 that permits the flow of medium. Cost-effectively the gas vessel 30 may be constructed from, for example, a group of standard industrial gas cylinders, or as a pipe section manufactured from the same material as the pipeline “C”. As high-pressure gas is stored in the internal space 31 of the gas vessel 30, which is also absorbed into the fire extinguishing material composition 1 located in the internal space 11 of the storage body 10 as its gas phase. In the case of intervention required at a use location 2 this gas is suitable for pushing the fire extinguishing material composition 1 in the internal space 11 of the storage body 10 through the given transport pipeline 20 into the dispersion device 3 at any endangered use location 2. In the case of the given embodiment a valve 33 is installed in the connection line 32 that regulates the flow of the gas in the internal space 31 of the gas vessel 30 into the internal space 11 of the storage body 10. Naturally, the valve 33 may also be located on the gas vessel 30 and on the storage body 10 as well.

[0037] Naturally, in the case of a system that extends over a significantly larger area it may become necessary to install several gas vessels 30, the reason for which is that there be a sufficient amount of propellant gas connected to a remote section of the pipeline “C” in the case of extinguishing being started towards any use location 2, which ensures the transporting of the fire extinguishing material 1 located more remotely. In addition, the remotely located gas vessels 30 make it possible to transport the fire extinguishing material 1 even in the case of height differences.

[0038] It may also be seen in FIG. 1 that the pipeline “C” forming the storage body 10 is coated with a material layer that reduces temperature fluctuations 5, at least on a part of the external surface 12 of the storage body 10, preferably on the larger part of it. The task of the material layer that reduces temperature fluctuations 5 is to protect the internal space 11 of the storage body 10 from greater temperature changes occurring in the external environment and from solar radiation, and also from excessive cooling and to ensure a nearly constant temperature within given limits in the internal space 11 of the storage body 10. This is important because under a substantially constant temperature the heat expansion of the fire extinguishing material composition 1 located in the internal space 11 of the storage body 10, changes in the proportion of the dissolved propellant gas, and therefore pressure fluctuations are minimal. This is needed, on the one hand, so that the internal space 11 of the storage body 10 can be filled with fire extinguishing material composition 1 to at least 94%. The smaller the amount of free gas phase in the internal space 11 of the storage body 10, the more certain it is that the amount of free gas phase accumulating at one place due to the deviation of the main axis “T” of the storage body 10 from the horizontal in the course of the installation of storage body 10 is able to disadvantageously influence the efficiency of extinguishing. On the other hand, the excessive and repeated heating and cooling of the fire extinguishing material composition 1 stored in the pipeline “C” (for example in pipeline sections exposed to solar radiation) would accelerate the ageing and deterioration of the foaming material, therefore by reducing heat fluctuation the lifetime of the fire extinguishing material 1 may be significantly extended.

[0039] It must be mentioned here that if the pipeline “C” of the storage body 10 is recessed under the soil, then the soil covering the external surface 12 of the storage body 10 itself may also serve as the material layer that reduces temperature fluctuations 5. Naturally in this case, the depth of installation of the pipeline “C” of the storage body 10 and the thickness and composition of the covering soil layer must comply with certain conditions.

[0040] If the pipeline “C” of the storage body 10 may not be located under the ground for its entire length, then it is possible to establish the material layer that reduces temperature fluctuations 5 as a heat-insulation covering fitted to the pipeline, as a shade or shield against solar radiation, or as reflective (light coloured) paint significantly reducing the absorption of solar radiation. In the latter two cases if protection against cooling is not realised, and the climate conditions make it justified, the fire extinguishing material composition 1 must be mixed with an antifreeze additive.

[0041] It is apparent from FIG. 1 that the main axis “T” of the pipeline “C” forming the storage body 10 is not a straight line, instead it complies with the positions of the use locations 2 and runs along a path that is not straight.

[0042] Moving over now to FIG. 1, it can be seen in it that the main axis “T” of the pipeline “C” of the storage body 10 is intentionally positioned in a manner that is not horizontal so that there is at least one point, but preferably a small section, in individual sections of the lower delimiting line 14 of the internal surface 13 delimiting the internal space 11 of the storage body 10 the lower point 14a of which is lower than the other parts of the lower delimiting line 14 of the internal surface 13 in the vicinity of the lower point 14a. Furthermore, there should be at least one point, but preferably a small section in individual sections of the upper delimiting line 15 of the internal surface 13 delimiting the internal space 11 of the storage body 10 the upper point 15a of which is higher than the other parts of the upper delimiting line 15 of the internal surface 13 in the vicinity of the upper point 15a.

[0043] The conscious laying of the pipeline “C” in this way ensures that the liquid phase of the fire extinguishing material composition 1 is located in the vicinity of the lower points 14a and that the gas phase that has left the fire extinguishing material composition 1 is located in the vicinity of the upper points 15a. If the path of the main axis “T” of the pipeline “C” is suitable, then the smaller gas pockets developing in the individual upper points 15a may be separated from the liquid phase accumulating in the lower points 14a, and therefore the size of the gas pockets will be so small that they are unable to influence the extinguishing efficiency during the extinguishing process in any way whatsoever.

[0044] In addition to this, purge fittings 40 may be located near to the upper points 15a with which, if necessary, the precipitated gas phase in the internal space 11 of the storage body 10 may be removed from the internal space 11 of the storage body 10, and optionally it may be forwarded to the gas vessel 30 with the help of an appropriate device, such as a compressor. What is more, the lower points 14a may be established along the path of the main axis “T” of the pipeline “C” so that the connections of the transport pipelines 20 are located in the vicinity of these lower points 14a. In this way it is completely impossible that in the case of a fire occurring at a given use location 2 a larger amount of propellant gas gets into the given transport pipeline 20 when extinguishing is started and this leading to accidental venting in the given pipeline section “C1”. With this it is even more certain that the efficiency of extinguishing can be increased.

[0045] It must be noted here that the storage body 10 and the gas vessel 30 of the fire extinguishing apparatus may be fitted with measuring and intervention elements the measure and indicate given characteristics of the internal space 11 of the storage body 10 and of the internal space 31 of the gas vessel 30, and make possible any necessary interventions. However, these structural units and known of in themselves, and have no uniqueness at all from the point of view of the present invention. Therefore, due to their known nature no description will be made of them.

[0046] During the use of the fire extinguishing apparatus according to the invention first of all the path of the pipeline “C” of the storage body 10 must be created. However, during this the earth excavators do not have to form a trench with a highly precise horizontal base, instead with consideration to the use locations 2 the main axis “T” of the storage body 10 can be determined so that at certain sections of the pipeline “C” the lower points 14a are on the lower delimiting line 14 of the internal surface 13 encompassing the internal space 11 of the storage body 10 and so that the upper points 15a are on the upper delimiting line 15. After positioning the storage body 10 the transport pipelines 20 can be connected to the lower points 14a, while purge fittings 40 may be fitted at the upper points 15a.

[0047] Following this, in a known way and therefore not detailed, the dispersion devices 3 and the abnormality-detecting bodies 60 linked to the transport pipelines 20 can be installed. Then the storage body 10 may be connected to the gas vessel 30 via the connection line 32, and then a filling fitting 6 and, if required, sectioning valves 50 may be fitted to the storage body.

[0048] After this the storage body 10 can be buried and in this way covering the external surface 12 of the storage body 10 with the material layer that reduces temperature fluctuations 5 is also realised.

[0049] Following the installation of the fire extinguishing apparatus the internal space 11 of the storage body 10 can be filled with the desired fire extinguishing material composition 1 via the filling fitting 6. In the case of several separate pipeline sections C1, C2 it is possible to install separate filling fittings 6 and by creating circulation between them the fire extinguishing material composition 1 in each of the pipeline sections C1, C2 can be homogenised. After filling has been completed, the high pressure gas phase can be filled into the internal space 31 of the gas vessel 30, then by opening or closing the valve 33 the high pressure gas phase can be filled into the internal space 11 of the storage body 10 via the connection line 32.

[0050] After filling the internal space 11 of the storage body 10 the purge fittings 40 of the storage body 10 may be opened and the gas pockets accumulated in the vicinity of the upper points 15a or a part of them can be released. In this way it can be ensured that when the fire extinguishing apparatus is in a condition ready for use the volume taken up by the fire extinguishing material composition 1 in the internal space 11 of the storage body is greater than 94% and the total volume of the gas pockets is smaller than 6%. From the point of view of the operation, the most preferable state of the gas pockets is when the technically achievable smallest amount of gas remains in the pipeline “C”, and when the amount of gas required for ensuring a constant extinguishing performance is stored in the gas vessel 30.

[0051] In the case of an emergency, e.g. fire, occurring at a use location 2 the ready-for-use fire extinguishing apparatus operates similarly to what is usual. The abnormality-detecting body 60 detects the occurrence of a fire and sends a signal to the central unit. Then by opening the trigger part-unit 4 belonging to the given use location 2 the central unit makes it possible for the fire extinguishing material composition 1 in the internal space 11 of the storage body 10 to pass into the transport pipeline 20 and from there to the dispersion device 3.

[0052] It is noted here that a solution may also be conceived in which the abnormality-detecting body 60 directly influences the operation of the trigger part-unit 4, and the trigger part-unit 4 launches the extinguishing process without intervention from the central unit.

[0053] The amount of foaming fire extinguishing material composition 1 flowing into the dispersion device 3 through the transport pipeline 20 reduces the amount of fire extinguishing material composition 1 remaining in the internal space 11 of the storage body 10, and so after a time its pressure would drop. At this time the valve 33 opens and the high-pressure gas phase forming a component of the fire extinguishing material composition 1 in the internal space 31 of the gas vessel 30 flows through the connection line 32 into the internal space 11 of the storage body 10, so restoring the pressure required for effective extinguishing, and the foaming ability of the fire extinguishing material composition 1.

[0054] After the extinguishing process has been completed the internal space 11 of the storage body 10 may be again filled with the required amount and composition of the fire extinguishing material composition 1 via the filling fitting 6.

[0055] It must be noted here that the costs of extinguishing may also be reduced if after completing the extinguishing at a given use location 2 the trigger part-unit 4 closes or the sectioning valves 50 are closed in the pipeline section “C1” and pipeline section “C2” of the pipeline “C” of the storage body 10 not involved in extinguishing. Naturally, this solution may be used if each pipeline section “C1” and pipeline section “C2” delimited by the sectioning valves 50 has a connection line 32 connection that makes it possible to directly take the high-pressure gas phase in the internal space 31 of the gas vessel 30 to the given pipeline section “C1” or pipeline section “C2”.

[0056] It is also important to note that the purge fittings 40 are not only suitable for regulating the size of the gas pockets developed in the vicinity of the upper points 15a. They also make it possible to regulate the composition of the fire extinguishing material composition 1 in the internal space 11 of the storage body 10, e.g. by removing the precipitated gas phase, and replacing it while mixing via the filling fitting 6.

[0057] The installed fire extinguishing apparatus according to the invention may be used to good effect in all cases when foam extinguishing needs to be performed with greater than usual effectiveness and economy with greater reliability, especially in the case of facilities located over a large area in the case of which the task could only be solved with several separate extinguishing systems.

LIST OF REFERENCES

[0058]

TABLE-US-00001 1 fire extinguishing material composition 2 use location 3 dispersion device 4 trigger part-unit 5 material layer that reduces temperature fluctuations 6 filling fitting 10 storage body 11 internal space 12 external surface 13 internal surface 14 lower delimiting line 14a lower point 15 upper delimiting line 15a upper point 20 transport pipeline 30 gas vessel 31 internal space 32 connection line 33 valve 40 purge fitting 50 sectioning valve 60 abnormality-detecting body “C” pipeline “C1” pipeline section “C2” pipeline section “T” main axis