EP0993322A1 - Impulse extinguisher - Google Patents

Abstract

The invention relates to an impulse extinguisher, which comprises a barrel (1), that has at least one connection to fill the barrel (1) with the quenching agent, an ejection opening for the quenching agent and a device (4) to eject the quenching agent by pressure. According to the invention said device (4) contains a recess (5) for an explosive material and a firing mechanism to (8) ignite it.

Description

Pulse extinguisher

The invention relates to a pulse extinguisher of the type specified in the preamble of claim 1.

From fire service reports and publications in the relevant journals, it is clear that fires often develop into large fires because the supply of extinguishing water is inadequate, because the throwing distances are too short to be extinguished with conventional jet pipes, e.g. due to large building complexes such as warehouses and production halls, and / or because the number of hazardous plastics and their countless connection options is constantly increasing. This results in more polluting pollutants from longer-lasting fires, contaminated extinguishing water due to longer extinguishing times and higher insurance damage. Recent fire disasters have also made it clear that in many cases successful fire fighting is not possible and that there is still a considerable need for research in fire protection.

Fire and industry experts have so far only partially reacted to this and are working on new, modern extinguishing devices. However, these devices are generally expensive and, due to their large dimensions and the required, specially trained IlOschkraft, reserved for individual professional and factory fire departments and only suitable for use in the event of major disasters. Known methods and devices of this type (DE 195 00 477 Cl) use, for example, the force of a detonation wave and the combination Extinguishing effect of water. This new technology is currently being tested and is to be used specifically for fighting forest fires. In the event of a forest fire, for example, a plastic hose (0 approx. 250 mm) with a detonating cord is laid parallel to the advancing flame front and then filled with water. As soon as the flame front reaches the hose, it is ignited and the fire is suddenly extinguished. Liquid fires can also be successfully extinguished in this way. Such methods and devices are, however, only suitable for use in the event of fire disasters and have the disadvantage that the plastic hoses must be laid according to the source of the fire and can only be ignited once.

In addition, a pulse extinguisher of the type described at the outset has become known, with which preselected quantities of extinguishing water, for example 1 1 to 30 1, are suddenly expelled from a pipe under a pressure generated by compressed air of, for example, 25 bar. The extinguishing water or other extinguishing agent is thereby distributed very finely, as a result of which a considerable increase in the surface area of the extinguishing agent and, as a result, considerable extinguishing agent savings are achieved. In addition, the pulse extinguisher can be operated inexpensively because the pressure can be generated, for example, with the compressed air from a conventional compressed air bottle carried with the pulse extinguisher, in particular a breathing protection bottle. It is noteworthy, however, that the extinguishing agent is expelled by the spontaneous expansion of a medium, here compressed air, and thus essentially depends on the difference in the pressures in the compressed air bottle or in the tube receiving the extinguishing agent. As a result, the achievable throwing distance is limited by the pressure with which the compressed air can usually be filled into a compressed air bottle, while the total amount of extinguishing agent that can be applied to the fire material largely depends on the capacity of the individual compressed air bottles and on the number of compressed air bottles available at the location of the fire. In practice, both the pressure and the available amount of compressed air are limited, so that an increase in performance can only be achieved with the help of a powerful compressor. However, the carrying of such compressors is generally undesirable for reasons of weight and space, in particular if they have to be transported to the fire site by means of a fire engine or the like. In contrast, the invention has for its object the pulse extinguisher of the beginning designated genus so that the throwing distances and extinguishable amounts are largely independent of the pressure and the available amount of a pressurized medium.

The characteristic features of claim 1 serve to solve this problem.

The pulse extinguisher according to the invention combines the advantages of the devices working with an explosive (DE 195 00 477 Cl) with those of the known pulse extinguishers. The pyrotechnic, explosive pressure build-up instead of compressed air results in faster firing sequences and longer throw distances, so that the pulse extinguisher according to the invention is suitable both for large fires and for preventing reignitions. It also enables effective fire fighting that saves extinguishing agents, shorter firefighting times, less contamination of extinguishing water, a reduction in polluting pollutants and a reduction in building damage. Finally, a combination of a muzzle flap and a closing mechanism, which is preferably additionally present, can ensure that the tube remains securely closed when the fire extinguishing agent is reloaded and that it can therefore be loaded with high pressure.

Further advantageous features of the invention emerge from the subclaims.

The invention is explained in more detail below in connection with the accompanying drawing using an exemplary embodiment. Show it:

1 shows a side view of a first embodiment of a pulse extinguisher according to the invention for an extinguishing agent;

FIG. 2 shows a top view of the pulse extinguisher according to FIG. 1;

Fig. 3 is a front view of the pulse cancellation device of Fig. 1;

4 shows a partial section along the line IV-IV of FIG. 1 with the omission of a hose line; 5 shows a longitudinal section through the rear end of a tube of the pulse extinguisher in a greatly enlarged illustration compared to FIG. 1;

6 shows a check valve of the pulse extinguisher according to FIG. 1 in a large magnification;

7 shows a section along the line VH-VH of FIG. 1 through an opening end of a tube of the pulse extinguisher;

8 and 9 are schematic representations of the operating states within a tube of the pulse extinguisher according to FIG. 1 when filled with an explosive propellant or when the propellant is blown out explosively;

10 shows a schematic illustration of a second embodiment of the pulse extinguishing device according to the invention;

11 to 13 in the representations corresponding to FIGS. 8 and 9 different operating states of the pulse extinguishing device according to FIG. 10; and

14 and 15 an alternative embodiment for a shut-off device of the pulse extinguisher according to FIG. 10 in a closed or open position.

According to FIGS. 1 to 5, a pulse extinguisher according to the invention according to a first variant, which is currently regarded as the best, contains a tube, for example cylindrical tube 1, which is intended for receiving and temporarily storing an extinguishing agent, in particular water. The tube 1 is in a central part with at least one for Filling with extinguishing agent provided connection 2 and has at its one, as a mouth or discharge opening for the extinguishing agent, a front end attached to the tube 1 housing 3 with a circular, rectangular or square cross section, for example. A device 4 mounted at the other, rear end of the pipe 1 is used to eject the extinguishing agent from the pipe 1. As shown in particular in FIG the pipe end inserted plug 6 is formed and is used to hold a partially indicated cartridge 7, which with a propellant or Gun or explosive is filled and preferably provided with a detonator or the like at its rear end. In addition, the device 4 contains an ignition mechanism 8, which, for example, has a firing pin 9 which is designed analogously to handguns or the like and can be struck against the firing fuse of the cartridge 7 by means of a spring 10 and through an opening in the bottom of the closure piece 6 to detonate the explosive in it. The explosive consists, for example, of a known NC (cellulose nitrate) powder, as is used, for example, for the cartridges of machine guns.

As shown in FIG. 5 in particular, the tube 1 is slidably mounted in a brake cylinder 12, which at its ends has an inwardly projecting end wall 13, 14 with a through-opening which has an inner cross-section corresponding essentially to the outer cross-section of the tube 1. In addition, the tube 1 is provided on its outer jacket with a flange 15 which comes close to the brake cylinder jacket, with an as between the flange 15 and the rear end wall 14

Compression spring trained spring 16 is supported, the tube 1 forward, i.e. 5 biased to the right until it rests with its flange 15 on the front end wall of the brake cylinder 12. An annular space between the pipe 1 and the brake cylinder 12 is filled with a brake fluid 17, in particular a hydraulic oil. In addition, it goes without saying that the tube 1 is hermetically sealed in the end walls 13 and 14 of the brake cylinder 12 by means of suitable and only schematically indicated seals 18.

The brake cylinder 12 is provided on its outer jacket with two bearing pins 19, by means of which the tube 1 is pivotally mounted in a fork-shaped mount 20 (FIGS. 1 and 3). The mount 20 is in turn supported by means of a swivel joint 21 on a base frame 22, which has a mounting flange 23 on its underside. This serves the purpose of mounting the entire pulse extinguisher, for example on the roof of a tank fire truck.

On a lateral part of the carriage 20, connecting pieces 24 (FIG. 4) are fastened, which can be connected by means of a hose line 25 (FIGS. 1 and 2) or the like to the two connections 2 of the pipe 1 which are present in the individual case, here two . The connecting pieces 24 are connected in terms of flow to a line 26 (FIG. 4), which is expediently mounted coaxially to the axis of rotation of the swivel joint 21 in the base frame 22 and ends below the mounting flange 23 so that it can be accommodated, for example, with a conventional supply line accommodated in the fire engine or the like for the extinguishing agent can be connected. Otherwise, the connections 2, the connecting pieces 24 and the lines 25, 26 are expediently provided with the connection fittings customary in fire-fighting vehicles.

The axis of rotation of the swivel joint 21 is arranged substantially vertically in the assembled state of the pulse extinguisher, while the pivot axis of the bearing pins 19 is arranged essentially horizontally. This makes it possible to turn the tube 1 on the one hand preferably by 360 ° about the vertical axis and on the other hand e.g. swivel in a range of -15 ° to + 75 ° around the horizontal axis.

As shown in FIG. 6 in particular, the extinguishing agent connection 2 is preferably provided with a check valve. For this purpose, it contains a housing 28 inserted into the tube 1 with a valve seat 29 and a valve body 31, which is preferably designed as a compression spring 30 against the valve seat 29 and thus biased into the closed position. The spring force of the spring 30 is preferably selected such that the valve body 31 only lifts off the valve seat 29 and thus opens the connection 2 when the pressure of the extinguishing agent in the line 25 (FIGS. 1 to 4) has a preselected value of, for example Exceeds 1.5 bar. This can e.g. be advantageous to ensure proper functioning of the fire extinguishing centrifugal pump.

The housing 3 on the tube end facing away from the receptacle 5 serves for the pivotable mounting of an orifice flap 34 (FIGS. 3 and 7) which, in the exemplary embodiment, consists of two wings 34a, 34b pivotably mounted on the tube 1 or in the housing 3 by means of hinges 33 7, which are shown in FIG. 7 with solid lines in their position sealing the tube end and with dashed lines in an open position in which they abut two stop walls 35 of the housing 3. These stop walls 35 serve the purpose of braking the two flap wings 34a, 34b after a swivel path of approximately 90 ° when the extinguishing agent is suddenly expelled from the pipe 1 or to prevent the flap wings 34a, 34b from further opening, in order to prevent injuries to the extinguishing personnel to avoid. The mouth flap 34 and its two wings 34a, 34b are each biased by a spring 36, which is designed, for example, as a cylindrical helical spring (torsion spring), into its closed position, in which it rests on an end wall 38 provided with a passage 37 for the medium of the housing 3. Therefore, the mouth flap 34 is automatically closed up to an extinguishing agent pressure in the pipe 1 predetermined by the springs 36, while it opens automatically when this pressure is exceeded.

To precisely control the closing force of the muzzle flap 34 while avoiding complex spring systems or the like, the muzzle flap 34 is assigned a closing mechanism 39 according to the invention, which keeps the muzzle flap 34 closed up to a preselected pressure and can be adjusted so that the muzzle flap 34 only at one Exactly specified extinguishing agent pressure in pipe 1 opens. This locking mechanism 39 can be designed as such, but it is preferably controlled electrically or electromagnetically, e.g. the muzzle flap is made of a ferromagnetic material and the portion of the housing having the passage 37 is wrapped with a winding 40 forming an electromagnet or by e.g. 38 individual electromagnets assigned to the wings 34a, 34b are mounted on the end wall. The electromagnetic force is selected so that it, at least in connection with the force of the springs 36, is greater than the charge pressure of the extinguishing agent in the tube 1, and therefore also greater than that

Charge pressure of the fire-fighting centrifugal pump to be connected to line 26 (FIGS. 1, 3 and 4). Since such pumps work in conventional fire engines with a pressure of up to approx. 16 bar, the closing force of the wings 34a, 34b is in the switched-on state of the closing mechanism 39 or when the winding 40 or the electromagnets are excited, e.g. set to 18 bar. When this closing force is exceeded, the muzzle flap 34 then opens suddenly and automatically. The closing force of the springs 36 need only be approximately 1 bar when the closing mechanism 39 is present in order to bring the two flap wings 34a, 34b back into the effective range of the closing mechanism 39 after the extinguishing agent has been expelled from the pipe 1.

The pulse extinguisher described so far is operated in the event of a fire as follows:

The pulse extinguisher is, for example, on the roof of a tank fire truck mounted, the connection 2 is connected via the hose lines 25 and line 26 to a fire extinguishing centrifugal pump usually present in the vehicle. Alternatively, the connection 2 or the line 26 can also be connected to any other device suitable for supplying an extinguishing agent, in particular water, and having a pump or the like.

Due to the pressure generated by the fire extinguishing centrifugal pump, e.g. The check valve in port 2 is opened at 16 bar, so that an extinguishing agent indicated schematically in FIGS. 8 and 9 flows into tube 1 at high speed. In order to keep the charging time small, the flow cross section of the

Check valve or check valve selected so large that flow rates of e.g. 30 to 40 1 / s are possible. With a volume of the tube 1 of e.g. 7.5 1 (in the closed state of the muzzle flap 34) this results in a charging time of approximately 0.2 to 0.25 seconds. The mouth flap 34 remains closed during the entire charging process, since its closing pressure is greater than the pressure of the extinguishing agent 41 in the pipe 1 even after the charging process has been completed. In order to prevent the extinguishing agent 41 from escaping from the pipe 1, the parts of the wings 34a, 34b and the end wall 38 (FIG. 7) that come into contact can be provided with seals 42. Apart from this, it goes without saying that the closure piece 6 is connected sufficiently tightly to the tube 1 when the cartridge 7 is inserted (FIG. 5), for which purpose between the closure piece 6 and the ignition mechanism 8 there is an additional closing wall 43 which also acts on the inserted cartridge 7 (Fig. 5) can be provided, which in this case is provided with an opening 44 aligned with the opening in the bottom of the closure piece 6.

With the aid of the device 4, in particular the firing pin 9 (FIG. 5), which can be triggered, for example, analogously to a handgun with a trigger, the detonator of the cartridge 7 is now ignited, as a result of which the propellant contained therein is brought to an explosion. As a result of the pressure wave emanating from one pipe end, which is indicated schematically in FIG. 9 by the reference numeral 45, the extinguishing agent 41 located in the pipe 1 is abruptly closed by the check valve located in the connection 2 by the automatically opening on the other pipe end located mouth flap 34, wherein it by pivoting the tube 1st around the bearing pin 19 or rotation of the tube 1 with the swivel joint 21 can be aimed specifically at the source of the fire. Therefore, the extinguishing agent 41 reaches the source of the fire in finely atomized form, so that the combination of extinguishing agent 41 and the pressure wave generated by it results in a high extinguishing effect. As soon as the extinguishing agent 41 has been expelled from the pipe 1, the orifice flap 34 automatically closes again under the influence of the springs 36 (FIG. 7) and due to the decreasing pressure in the pipe 1, whereupon the next filling process and then another firing is initiated can be. To improve the opening and closing function of the muzzle flap 34, it is possible to design the locking mechanism 39 (FIG. 7) to be controllable and to control it so that it is switched off immediately before or when the cartridge 7 is ignited, in order to incline the muzzle flap 34 enlarge, open automatically and abruptly, whereas it is reactivated immediately after the ignition process so that it is already reactivated when the wings 34a, 34b are brought up to the end wall 38.

In principle, a new cartridge 7 can be inserted into the receptacle 5 (FIG. 5) by hand, for example by analogous to loading a rifle or a cannon, the closing wall 43, not shown, including the ignition mechanism 8, which is arranged behind the breech 6, is opened or removed, the used cartridge 7 is removed, a new cartridge 7 is inserted and the closing wall 43 is closed again. It goes without saying that the closing wall 43 must be closable in such a way that it cannot open even when the cartridge 7 is ignited. Alternatively, it is also possible to provide the device 4 (FIGS. 1 and 2) with an automatically operating loading device, which has a schematically indicated magazine 46 and enables the cartridges 7 to be replaced at high speed. Charging devices of this type, which can also have an integrated ignition mechanism if required, are generally known in numerous weapon systems and can be used analogously in the pulse extinguisher described. By using such loading devices that work at high speed, the shot sequence that can be achieved is practically only dependent on the time interval that is required for filling the pipe 1 with extinguishing agent.

When using a cartridge 7, for example with 0.05 kg of propellant powder NC A 3502 is filled, the described pulse extinguishing device achieves an explosion energy of approx. 3.5 Kj / kg, which has a maximum gas force of approx. 1500 bar and a water ejection speed of approx 180 m / s. The entire ejection cycle takes place within a time span of approx. 10 to 20 m / s, so that correspondingly rapid firing sequences can be achieved.

The brake cylinder 12 shown schematically in FIG. 5 serves to introduce the recoil forces into the base frame 22 (FIG. 1) or via its mounting flange 23 into the fire truck. The brake cylinder 12 brakes the tube 1, which is accelerated backwards when the cartridge 7 is fired, to a standstill, the braking taking place in particular by the fact that the liquid 18 in the brake cylinder 12 during the return through the narrow annular gap between the flange 15 of the tube 1 and the Brake cylinder jacket (Fig. 5) must be pressed, while the spring 16 is tensioned. After completion of the braking process, the advance spring 16 returns the tube 1 to its initial position.

As shown in FIG. 5, the tube 1 preferably has an internal cross section which initially widens from the receptacle 5 in the direction of the mouth flap 34 to a maximum value. The resulting, e.g. beginning at the receptacle 5, in the case of a cylindrical tube 1 essentially conical extension 47 serves the purpose of limiting the extension angle a in such a way that no detachment phenomena occur within the explosion wave, which could prevent the extinguishing agent from being completely expelled from the tube 1. The expansive angle o; can be determined from flow theory using the Reynolds number and the permissible critical angle.

The pulse extinguishing device described is thus based on the knowledge that, unlike in the prior art, the extinguishing agent can be fired like a projectile with a device which is designed for this purpose in a manner similar to, for example, a rifle or a cannon, in that the firing of the Extinguishing agent provided tube 1 to prevent leakage of the extinguishing agent during the loading process, until each shot is hermetically sealed at each end. The individual in the Cartridges 7 existing propellants, the amounts of propellant and the achievable explosion energies are to be measured in individual cases on the basis of the volume of the tube 1 and on the desired throwing distances.

In a second embodiment of the invention, shown schematically in Fig. 10, a gaseous or liquid propellant or explosive, e.g. an acetylene / oxygen mixture or gasoline. For this purpose, a tube 51, analogous to FIG. 5, is designed like a diffuser at its rear end and provided with an opening 52 at its bottom. Furthermore, a device 53 intended for ejecting an extinguishing agent under pressure is provided, which has a receptacle 54 in the form of a pressure container connected to the pipe 51 via the opening 52. The receptacle 54 has a connection 55, which is connected via a line 56 to a metering device 57, which in turn via lines 58, 59, each with a storage container 60, 61 for a gas, e.g. Acetylene or oxygen, is connected. The metering device 57 serves the purpose of mixing the gases in the storage containers 60, 61 in a ratio that is suitable for the shock wave to be generated in the pipe 51 in the individual case. Alternatively, it would of course be possible to provide only one storage container which is filled with a single gas which can be exploded or with a correspondingly metered gas mixture.

The device 53 also has a control module 62, which is connected via a line 63, 64 to the metering device 57 and an ignition mechanism 65, which here is e.g. contains a spark plug designed analogously to internal combustion or explosion engines and is inserted into a wall of the pressure vessel 54. The control module 62 can be a manually controllable component or also e.g. act as a usual personal computer (PC) or the like.

The embodiment according to FIG. 10 can be operated, for example, in the manner described below.

11 roughly schematically shows, the tube 51 is provided with a connection 67 corresponding to the connection 2 according to FIGS. 1 to 9, in order to be able to fill it with an extinguishing agent 68, for example water. The extinguishing agent 68 is the same as that described first Exemplary embodiment supplied with a conventional centrifugal pump. In contrast to the first exemplary embodiment, however, the extinguishing agent 68 is supplied continuously, while the extinguishing agent 68 is in turn impulsed. For this purpose, the ignition mechanism 65 is ignited by the control module 62 at preselected intervals and the gas or gas mixture in the pressure vessel 54 is thereby caused to explode. This has the result that, analogously to the first exemplary embodiment, in which a propellant cartridge 7 is brought to explosion, a pressure wave 69, indicated schematically in FIG. 12, arises, which axially expels the extinguishing agent 68 from the tube 51 at high speed, so that it reaches the source of the fire in finely atomized form. After each ejection or shot, on the one hand the tube 51 begins to fill again with the extinguishing agent 68, while at the same time, under the control of the control module 62, the pressure vessel 54 is filled again with the gas or gas mixture.

Depending on the pressure or the speed at which the extinguishing agent 68 is introduced into the tube 51, two variants are possible in the described mode of operation. In the one variant which is shown in Fig. 12 and is particularly inexpensive and in which the extinguishing agent 68 is substantially perpendicular to the direction of ejection, i.e. When the pipe 51 is introduced perpendicular to the axis of the pipe 51, the extinguishing agent 68 flows between two shots at a comparatively low speed and therefore in a comparatively short, strongly curved jet 70 from the front discharge opening of the pipe 51. It then lands on the ground at a comparatively short distance from the pipe opening. In contrast, in the variant shown in FIG. 13, by introducing the extinguishing agent 68 into the tube 51 obliquely or parallel to the tube axis, the extinguishing agent is also achieved between two shots at high speed and therefore in a largely linear jet 71 from the discharge opening of the Pipe 51 flows out, the jet 71 allows a comparatively large throw and the pipe 51 can therefore be used between two shots like a normal water cannon. This has the advantage that the extinguishing agent 68 reaches the source of the fire alternately in a highly atomized form or in a conventional jet, and therefore there is no pause for extinguishing agent between two shots.

When using the exemplary embodiment according to FIGS. 10 to 13, the inflow Speed or the supply pressure of the extinguishing agent and the cross sections of the tube 51 and the connection 67 are coordinated with one another in such a way that the desired effect according to FIG. 12 or 13 results in the individual case. While in the embodiment according to FIG. 12, because of the introduction of the extinguishing agent perpendicular to the pipe axis and due to the resulting friction losses or the like, no long throw distances can be achieved, the extinguishing agent in the embodiment according to FIG Connection 67 attached, designed in the manner of a pipe bend, nozzle 72 (FIG. 13), which has an outflow opening arranged coaxially in the pipe 51 and opened in the direction of the discharge opening of the pipe 51, into the pipe 51. If the tube 51 is to be able to work as a normal water cannon between two shots, a cross section of the nozzle 72 of, for example, 32 mm can prove expedient with a tube cross section of, for example, 80 mm. Alternatively, it would also be possible to introduce the extinguishing agent into the tube 51 from one or more sides through openings 73 formed in the tube wall, which are inclined in the direction of the discharge opening and arranged at an angle of, for example, 45 ° or another suitable angle to the tube axis are. For the rest, when using the embodiment according to FIG. 10, essentially the same conditions can be selected as in the embodiment according to FIGS. 1 to 9, wherein the tube 54 can also be provided with a brake cylinder corresponding to the brake cylinder 12 according to FIG. 5.

In order to prevent the extinguishing agent 68 from flowing back into the pipe 51 and thereby unintentionally reaching the pressure container 54, it can be particularly advantageous, in particular in the embodiment according to FIG. 12, between the section of the pipe 51 receiving the extinguishing agent and the section receiving the explosive of the pressure vessel 54 to provide a shut-off element 74, in particular a controllable shut-off element 74, as shown for example in FIG. 10. The shut-off element 74 here consists of a slide which is displaceably guided in the tube wall and perpendicular to the tube axis and which closes the tube cross section in a closed position shown in dashed lines, on the other hand releases the tube cross section in an open position shown in solid lines. The direction of displacement is indicated by a double arrow y. To move the shut-off member 74 is a schematically indicated locking mechanism 75, z. B. contains a motor-controlled crank, a pneumatic or hydraulic cylinder / piston arrangement, a solenoid or the like a line 76 is connected to the control module 62. This makes it possible, on the one hand, to control the shut-off element 74 after a shot of extinguishing agent has been fired and before the introduction of the explosive into the pressure vessel 54 under the control of the control module 62 into the dashed position closing the pipe cross section, in order to mix the explosive with the extinguishing agent to avoid. Before firing an extinguishing agent shot and shortly before actuation of the ignition mechanism 65, the shut-off element 74 is moved into the position releasing the pipe cross-section, so that the shock wave arising during the explosion can now penetrate the pipe 51 unhindered. The arrangement is preferably such that the shut-off element 74 is completely retracted into the tube wall in the open position and is therefore not exposed to the action of the shock waves.

The shut-off element 77 according to FIGS. 14 and 15 can also be used with particular advantage for the purpose described. In this embodiment, the shut-off member 77 consists of a rotating body 78 which is rotatable in the bearing pin 79

The lateral surface of a cylindrical pipe socket 80 connecting the pipe 51 to the pressure vessel 54 is mounted. One of the bearing journals 79 is connected to a schematically illustrated locking mechanism 81, for example a drive motor, in particular an electric stepping motor, and can be rotated by it about an axis 82 arranged perpendicular to the tube axis. The rotating body 78 contains a passage 83, the cross section of which essentially corresponds to the inner cross section of the pipe socket 80. In addition, the rotating body 78 is designed such that it blocks the passage 84 formed by the pipe socket 80 when it is in a closed position according to FIG. 14. On the other hand, if the rotating body 78 is in an open position according to FIG. 15 after a rotation through 90 ° in one or the other direction of rotation, then its passage 83 forms an essentially stepless, continuous continuation of the passage 84. The closing mechanism 81 can, like the closing mechanism 75 19 are under the control of the control module 62. A major advantage of the embodiment according to FIGS. 14 and 15 is, however, that the shut-off element 77 can be set in a continuous rotation about the axis 82 and thereby alternately opens or blocks the passage 84. The ignition mechanism 65 (FIG. 10) is controlled in this case so that the explosion occurs whenever the shut-off element 77 is currently in the open position according to FIG. 15. The invention has numerous advantages. A particular advantage is that the throwing range of the extinguishing agent can largely be preselected by the choice of the explosive used. The throwing distance can also be changed individually by setting the mixing ratio of, for example, an acetylene / oxygen mixture. In addition, there is the advantage that a given amount of explosives is suitable for far more extinguishing agent shots than this applies to a corresponding amount of compressed air, because only very small amounts of explosive are required to generate the required shock wave by explosion. Furthermore, it is not necessary to introduce the explosive under pressure into the pressure container 54 (FIG. 10) or the chamber 5 (FIG. 5). Finally, the shut-off device 77 described with reference to FIGS. 14 and 15 has the advantage that it can also be used instead of the mouth flap 34 (FIG. 7). In this case, it is only necessary to insert the shut-off element 77 analogously to FIGS. 14 and 15 into the pipe end having the discharge opening and to control it with the aid of a suitable control, for example the control module 62 according to FIG. 10, so that it is just before a shot 15 and is moved shortly after a shot in the closed position of FIG. 14. In a corresponding manner, the shut-off element 74 according to FIG. 10 could also be provided instead of the mouth flap 34.

The invention is not limited to the exemplary embodiments described, which can be modified in many ways. For example, the pipe 1 could additionally be provided with a vent valve which, while charging the air in the pipe 1, does not allow any extinguishing agent to escape. It would also be possible to provide ignition devices other than those described, in particular those that operate electrically. Furthermore, it is possible to assign electric motors or the like to the swivel joint 21 and the tube 1 or the brake cylinder 12 in such a way that the rotation or pivoting of the tube 1 can be carried out automatically. The locking mechanism 39, 75 and 81 described can also be modified in a variety of ways. Although its design as an adhesive closure (Fig. 7), lifting device (Fig. 10) or motor (Fig. 14, 15) is preferred, other embodiments are also conceivable, in particular those with quickly controllable, form-fitting locking means or the like, whereby the control means provided for unlocking are expediently combined with the ignition device in such a way that unlocking takes place automatically when the explosive is ignited.

Claims

In addition, with the described locking mechanism provided with electromagnets, it is of course also possible to provide adhesive closures in the form of permanent magnets. Apart from this, such materials should be used in the technical implementation of the pulse extinguisher and dimensions selected such that the total weight of the pulse extinguisher is below a preselected critical value. Calculations show that the described pulse extinguisher, designed for a capacity of 7.5 l of extinguishing agent, can be manufactured with a total weight of approx. 130 kg. The term "explosives" in connection with the invention is understood to mean those explosive substances which are capable of a chemical reaction which is so rapid that an explosion occurs when it occurs, for example, through blows or sparks or with the aid of detonators or the like subjected to mechanical stress. It does not matter whether these substances are themselves explosive or are only made explosive when mixed with other substances. In addition, both the solid and the gaseous and liquid explosives can be mixtures, as is the case for. B. was explained based on the mixture of acetylene / oxygen. Finally, it goes without saying that the described features of the pulse extinguisher can also be provided in combinations other than those shown and described. Expectations

1. pulse extinguisher with a tube (1), the at least one for filling the tube (1.51) with the extinguishing agent (41.68) certain connection (2.67), an ejection opening for the extinguishing agent (41.68) and one Device (4,53) for ejecting the extinguishing agent (41,68) under pressure, characterized in that the device (4,53) has a receptacle (5,54) for an explosive and an ignition mechanism (8, 65) contains.

2. pulse extinguisher according to claim 1, characterized in that the receptacle (54) is a with the tube (1) connected to receive a gaseous or liquid explosive pressure vessel.

3. pulse extinguisher according to claim 2, characterized in that the ignition mechanism (65) contains a pressure plug associated with the spark plug.

4. pulse extinguisher according to claim 2 or 3, characterized in that the pressure vessel is connected to a metering device (57) for the explosive.

5. pulse extinguisher according to claim 1, characterized in that the device (4) contains a propellant cartridge (7).

6. pulse extinguisher according to claim 5, characterized in that the receptacle (5) consists of a chamber for receiving the cartridge (7), which is arranged at the end of the tube (1) remote from the discharge opening.

7. pulse extinguisher according to claim 5 or 6, characterized in that the ignition mechanism has a firing pin (9) for acting on an igniter of the cartridge (7).

8. pulse extinguisher according to one of claims 5 to 7, characterized in that it has an automatic loading device with a magazine (45) for reloading or replacing the cartridge (7).

9. pulse extinguisher according to one of claims 1 to 8, characterized in that the discharge opening is associated with an automatically opening and closing mouth flap (34).

10. pulse extinguisher according to claim 9, characterized in that the mouth flap (34) is associated with a locking mechanism (39).

11. Pulse extinguisher according to claim 10, characterized in that the closing mechanism (39) is designed as an adhesive closure and so that the mouth flap (34) is closed up to a preselected pressure in the tube (1) and opens automatically when this pressure is exceeded .

12. pulse extinguisher according to claim 11, characterized in that the preselected pressure is above the boost pressure of a fire-fighting centrifugal pump intended for filling the tube (1).

13. pulse extinguisher according to one of claims 1 to 12, characterized in that the extinguishing agent connection (2) is provided with a check valve.

14. Pulse extinguisher according to one of claims 1 to 13, characterized in that the tube (1.54) has an internal cross section which extends from the receptacle (5.54) to a maximum diffuser shape.

15. Pulse extinguisher according to one of claims 1 to 14, characterized in that the tube (1) is pivotally mounted on a carriage (20) by means of bearing pins (19).

16. Pulse extinguisher according to one of claims 1 to 15, characterized in that the tube (1) is mounted in a brake cylinder (12) and is provided on its outer jacket with a flange (15) and that between the flange (15) and an end wall (14) of the brake cylinder (12) a return spring (16) is supported.

17. Pulse extinguisher according to one of claims 2 to 16, characterized in that a shut-off element (74, 77) is provided for preventing the mixing of the explosive and the extinguishing agent.

18. Pulse extinguisher according to claim 17, characterized in that the shut-off device (74, 77) is assigned a controllable closing mechanism (75, 81).

19. Pulse extinguisher according to one of claims 10 to 18, characterized in that a control device (62) for the closing mechanism (39, 75, 81) and the ignition mechanism (8, 65) is provided.