Patent Application
20230191177
The subject matter relates to a fire-fighting nozzle, a fire-fighting system, and a method of operating a fire-fighting system.
Fire-fighting systems with thermally activated nozzles are usually either dry-biased or wet-biased. The advantage of dry-biased systems is their frost resistance, since in the idle state, i.e. when no fire has been detected and the system is ready for operation, the supply lines and firefighting nozzles are free of extinguishing fluid, in particular water.
Liquid extinguishing fluid, especially water, even if it has additives, is subject to the risk of freezing, and when it freezes, the natural expansion of the water can cause damage to the piping and nozzles. This problem does not exist initially with dry-biased systems.
However, when such dry-biased fire-fighting systems are activated, i.e., moved from their rest state to the active state in the event of a fire or fire alarm, the piping is flooded with extinguishing fluid. The extinguishing fluid flows through the piping and reaches the fire-fighting nozzles. The extinguishing fluid is expelled from the system by the triggering fire-fighting nozzles. These firefighting nozzles must be replaced after successful firefighting.
On the other hand, however, those firefighting nozzles that were not triggered during activation remain mounted in the system after activation. However, due to the flooding of the piping system during activation, the supply lines to these firefighting nozzles are also flooded with extinguishing fluid.
After replacing the activated fire-fighting nozzles, the piping of the system is drained and the system is dry-biased again. After draining, there should be no more extinguishing fluid in the piping. However, the extinguishing fluid that remains as residue in those fire-fighting nozzles that have not been triggered is problematic. It cannot always be ensured that the extinguishing fluid flows out of all firefighting nozzles when emptied, driven by gravity. However, this non-draining extinguishing fluid represents a significant potential for damage, as it can freeze and then cause damage on site due to its expansion.
Due to installation space constraints, Fire-fighting systems, especially the piping, are usually mounted below the ceiling. In the simplest case, the firefighting nozzles could be installed in the angled section of the piping facing the ceiling so that it drains naturally, gravity-driven. In this case, however, the fire-fighting nozzles are oriented toward the ceiling and would initially discharge the extinguishing fluid toward the ceiling in the event of activation.
The effect can be minimized by constructive measures, but the pipeline running underneath represents an obstacle to spraying. This limits the spread of the extinguishing fluid and its distribution.
However, since fire-fighting nozzles are qualified for a specific application, their location in the room is relevant for correct installation. A fire-fighting nozzle that is qualified for a vertically downward application cannot be readily used in an upward, particularly vertically upward, direction. This would be contrary to the qualification and would be an installation defect.
The effort to qualify fire-fighting nozzles is considerable, so that there is a need to be able to install already qualified fire-fighting nozzles in dry-biased fire-fighting systems in a frost-proof manner.
Thus, the subject matter was based on the object of providing a firefighting nozzle, a firefighting system and a method that allows frost-proof use in dry-biased firefighting systems.
This object is solved by a fire-fighting nozzle according to claim 1, a fire-fighting system according to claim 15, and a method according to claim 16.
A fire-fighting nozzle of the subject matter may be provided with either a sprinkler nozzle insert or a fog nozzle insert. When a fog nozzle insert is used, the extinguishing fluid is finely atomized, in particular with high pressure in the event of a fire, which promises a particularly good fire-fighting success.
The extinguishing fluid is in particular water, but can also be another liquid. Whenever water is mentioned in the following, any other liquid extinguishing fluid can also be meant. Whenever extinguishing fluid is mentioned in the following, water or any other liquid extinguishing fluid can in any event be meant.
The present fire-fighting system is in particular a dry-biased fire-fighting system. The pipelines of the dry-biased fire-fighting system are pressurized with a rest gas pressure in the rest state. Fire detection means, which in particular can also be arranged directly at the fire-fighting nozzle, can detect a fire, for example by a rising temperature. In such a case, the fire detection means are triggered and allow gas to escape from the piping system. The associated pressure loss can be detected and the Fire-fighting system can be flooded with extinguishing fluid.
At those firefighting nozzles that are assigned to the fire, e.g. because they have been triggered, the extinguishing water can escape and be used to fight the fire. After the fire has been successfully fought, the extinguishing water is drained from the piping system and the activated fire-fighting nozzles are replaced. However, firefighting nozzles that have not been activated remain in the system.
For draining the non-replaced firefighting nozzles, the nozzles have a tubular inlet with an inlet opening, the inlet extending along a longitudinal axis from the inlet opening in the direction of a sealing valve. The fire-fighting nozzle is attached to a pipeline with an inlet opening and extinguishing fluid can enter the tubular inlet via the inlet opening and flow from there in the direction of the sealing valve. In the installed state of the nozzle, the longitudinal axis is horizontal. The position of the longitudinal axis relative to the horizontal preferably has a tolerance range of −5 up to 45°.
The shut-off valve may be closed in the rest state and open only in the activation state.
A tubular outlet with at least one nozzle opening may be provided on the shut-off valve, the outlet extending along a transverse axis transverse to the longitudinal direction towards the nozzle opening. That is, the inlet and outlet or longitudinal axis and transverse axis extend in an L-shape relative to each other. The inlet is a first leg along a first direction and the outlet is a second leg along a second direction. This allows the fire-fighting nozzle to be positioned on the pipework at a suspended ceiling installation and the discharge direction of the nozzle orifice to be positioned downwardly. This allows those nozzle inserts to be inserted into the nozzle openings that are qualified for a downward spray pattern. By aligning the outflow direction in the installation position essentially vertically, any spray pattern can be generated by the nozzle, especially in the downward area, since the area below is free of spray obstacles in the form of piping.
However, the height of the nozzle is less than if the inlet and outlet extended along a common axis.
The shut-off valve is located between the inlet and the nozzle opening. The shut-off valve is arranged to seal the outlet from the inlet in a sealing area when not in use. Thus, extinguishing fluid cannot pass from the inlet via the sealing area to the nozzle opening. For this purpose, the shut-off valve must first open, which only happens in the case of activation.
After activation, the nozzle must be drained. For this purpose, it is now proposed that a radial distance of the sealing area from the longitudinal axis is smaller than or equal to a smallest radial distance of the inner circumferential surface of the tubular inlet from the longitudinal axis in an area between the inlet opening and the sealing area. In particular, the longitudinal axis is the center axis of the inlet, especially the tubular inlet. Starting from this central axis, the inner circumferential surface of the tubular inlet has a radial distance. In the area between the inlet opening and the sealing area, the inner lateral surface has a radial distance from the longitudinal axis. This can be constant or variable, stepped or continuous between the inlet opening and the sealing area. The radial distance increases in the tubular inlet starting from the inlet opening towards the sealing area. In particular, the diameter of the tubular inlet tapers in the direction of the sealing area.
The radial distance of the sealing area from the longitudinal axis is smaller than the radial distance from the longitudinal axis in the area between the inlet opening and the sealing area. In particular, the radial distance always increases starting from the sealing area towards the inlet opening in the tubular inlet, and the increase in the radial distance can be continuous and/or gradual. This smallest radial distance in the sealing area ensures that, in a horizontal mounting position of the inlet of the fire-fighting nozzle, extinguishing fluid flows safely and reliably out of the sealing area via the inner circumferential surface out of the fire-fighting nozzle, driven by gravity.
In particular, the fire-fighting nozzle is mounted on the pipeline in a horizontal plane, meaning that the longitudinal axis is in a horizontal plane in the mounting position of the fire-fighting nozzle. The design also allows tolerances from the horizontal, with the range preferably being in the between −5 up to 45° rising towards the sealing valve. In particular, the supply line to the fire-fighting nozzle also runs in this plane. If the radial distance of the sealing area is smaller than any radial distance of the inner lateral surface from the longitudinal axis between the sealing area and the inlet opening, it is then ensured that extinguishing fluid flows from the sealing area towards the inlet opening driven by gravity and thus drains the fire-fighting nozzle.
According to one embodiment, it is proposed that a spring acts on a valve stem of the shut-off valve. This spring can be used to move the shut-off valve from a rest position to an activation position. The shut-off valve can be released for movement when activated, and this movement is caused by the spring force. In particular, the shut-off valve is hinged to fire detection means, in particular mounted to the fire detection means. When the fire detection means is triggered, this bearing is released and the shut-off valve or the valve stem can be moved in the direction of the fire detection means, driven by the spring force. Hereby, the sealing area is released and the extinguishing fluid can flow out of the fire-fighting nozzle.
According to one embodiment, it is proposed that the spring is mounted against a radially inwardly facing collar on the tubular inlet. In particular, the sealing valve moves transversely in the longitudinal direction. Viewed in the longitudinal direction, a fire detection means is located, for example, on the side of the inlet opposite the inlet opening. The inlet opening and fire detection means are thus located at distal ends of the tubular inlet. The spring on the side of the sealing valve facing the inlet opening is mounted on a collar. The collar runs along the inner lateral surface of the inlet and points inwards. This allows the spring to exert a force on the shut-off valve acting in the longitudinal direction away from the inlet opening, which in the event of activation, when the shut-off valve is released, causes the shut-off valve to move transversely along the longitudinal axis in the direction of the fire detection means and the sealing area is released by the shut-off valve. However, this circumferential collar is responsible for the fact that, starting from the inlet opening behind this collar, a volume is created between the collar and the sealing area that cannot be drained by gravity. Now, in order to allow gravity-driven drainage, it is proposed that the collar has an opening (e.g. groove) running in the longitudinal direction, especially in the area of the bottom of the tubular inlet facing the outlet. The opening has a bottom (e.g. groove bottom) which is in particular planar with the inner circumferential surface of the tubular inlet abutting thereon in the direction of the inlet opening, or a smaller radial distance than the tubular inlet towards the inlet opening. The base may be planar with the inner lateral surface of the tubular inlet adjacent thereto in the direction of the sealing region, or may have a greater radial distance than the tubular inlet toward the sealing region. The bottom of the opening may extend longitudinally toward the sealing region beyond the walls of the collar. The base may form a step in the inner lateral surface.
In particular, the walls of the opening extend radially inward. In the installation position, the longitudinal axis runs in a horizontal line. The opening is in particular in the region of the lowest point there of the inner lateral surface of the tubular inlet. The transverse axis then runs vertically in the vertical.
According to one embodiment, it is proposed that the opening spans an arc angle of more than 1 degree and less than 45 degrees. In particular, the opening is provided in the lower region of the inlet. A larger arc angle could lead to the spring no longer having enough contact surface. A smaller arc angle could result in drainage no longer being sufficiently good.
According to one embodiment, it is proposed that the spring is supported against a frontal bottom of the outlet opposite the nozzle opening. In this case, the valve stem of the shut-off valve is mounted so that it can move in particular parallel to the transverse axis. The valve stem is pressed by the spring in the direction of the nozzle opening. When the shut-off valve is released, the valve stem moves in the direction of the nozzle opening due to the spring force. For this purpose, the spring is mounted on the side of the outlet opposite the nozzle opening and can thus exert a spring force.
According to one embodiment, it is proposed that a spring force of the spring acts on the valve stem in such a way that the valve stem is pressed against a fire detection means and is moved in the direction of the fire detection means when the fire detection means is triggered. In the rest state, the fire detection means exerts a counterforce to the spring force. In the activation state, this force is deactivated and the valve stem can be moved towards the fire detection means by the spring force.
According to one embodiment, it is proposed that the valve stem is mounted movably in the direction of the longitudinal axis or in the direction of the transverse axis. This bearing is particularly suitable for a transversal movement along the longitudinal axis or the transversal axis.
According to one embodiment, it is proposed that the sealing means seals an annular space between the valve stem and the tubular inlet or the tubular outlet. In case of movement of the valve stem in the direction of the longitudinal axis, the sealing means is arranged at the tubular inlet. In the case of movement of the valve stem in the direction of the transverse axis, the sealing means is arranged at the tubular outlet. The sealing means is always arranged in the area of the transition between inlet and outlet. Due to the movement, the sealing means is moved into a region where it no longer creates a seal of the annular space and thus extinguishing fluid can flow from the inlet to the outlet.
According to one embodiment, it is proposed that the cross-section of the tubular inlet is point-symmetrical with respect to the longitudinal axis. Also, it is proposed that the cross-section of the tubular outlet is point-symmetrical with respect to the transverse axis.
According to one embodiment, it is proposed that the nozzle opening is formed for receiving a nozzle insert, in particular for receiving a fog nozzle insert. In particular, the nozzle opening may be formed for a screw insert. A nozzle insert may be formed for the corresponding application purpose and may be, for example, a fogging nozzle or a sprinkler nozzle. This is preferably screwed into the nozzle opening and forms the end of the fire-fighting nozzle. The extinguishing fluid is discharged from the nozzle insert in the case of activation.
According to one embodiment, it is proposed that the inlet opening is formed for arrangement on a mounting fitting of a distribution pipe. An attachment fitting may be, for example, a tee, a tapping clamp, an attachment clamp or the like. In particular, the Fire-fighting nozzle may be bolted thereto. Likewise, the nozzle can also be connected to the pipe network, for example, via press connectors.
According to one embodiment, it is proposed that the fire detection means is a glass barrel. The glass barrel is loaded with a spring force by the spring and the valve stem. In case of fire, the glass barrel bursts and the valve stem is released and moved towards the glass barrel driven by the spring force.
In another aspect, there is provided a fire-fighting system according to claim 15, wherein a supply line supplies extinguishing fluid to the fire-fighting nozzle. A nozzle insert is disposed within the fire-fighting nozzle. In another aspect, there is provided a method of fire-fighting according to claim 16.
In the following, the subject matter is explained in more detail with reference to a drawing showing embodiments. In the drawing show:
The fire-fighting nozzle 2 is sealingly screwed to the fitting 6 with the inlet 4 via a screw-on clamp 10. The inlet 4 has an inlet opening 4a. The inlet opening 4a is circumscribed by an inner circumferential surface 4b of the inlet 4. The inlet 4 extends along a longitudinal axis 12. In the installed state, the longitudinal axis 12 extends in a horizontal direction. A transverse axis 14 extends transversely to this longitudinal axis 12. In the installed state, the transverse axis 14 extends in particular in the vertical.
The inlet 4 is connected to a tubular outlet 18 via a sealing area 16. The outlet 18 runs along the transverse axis 14. An outlet opening 18a is provided at the outlet 18. A nozzle insert 20 can be inserted, in particular screwed, into the outlet opening 18a.
In the sealing area 16, a circumferential seal 22 is arranged on a valve stem 24. A collar 26 is arranged on the inner lateral surface 4b remote from the inlet opening 4a and points radially inwards. A spring 28 is hinged to this collar 26. The spring 28 is tensioned in the rest state. The spring 28 is held in the tensioned state by a glass barrel 30. The valve stem 24 is attached to the glass barrel 30.
The tubular inlet 4 extends between the inlet opening 4a and the collar 26, and between the collar 26 and the sealing area 16.
In the rest state, the tubular inlet 8 is subjected to a rest pressure which presses against the valve stem 24. As a result, the glass barrel 30 is pressurized.
If a fire occurs, the increased temperature causes the glass barrel 30 to burst, so that the spring 28 pushes the valve stem 24 out of the inlet 4 in the direction of the longitudinal axis 12. The seal 22 of the sealing area 16 enters a clearance 32, allowing air to escape from the orifice 20 past the seal 22. Such a loss of pressure is detected in the pipeline 8 and results in the pipeline 8 being flooded with an extinguishing liquid. The extinguishing liquid can then come to the nozzle insert 20 via the inlet 4 and the free space 32 and be expelled there.
However, such activation occurs only at nozzles 2 which are located immediately or in close proximity above the fire load. Nozzles remote therefrom do not activate, since the glass barrel 30 does not burst.
Nevertheless, the pipe 8 is flooded and extinguishing fluid also reaches the inlet 4a in non-activated nozzles 2, i.e. the area between the collar 26 and the sealing area 16, in particular up to the seal 22.
After successful fire-fighting, the pipeline 8 is emptied. In order to prevent extinguishing fluid from remaining in the nozzle 2, in particular between the inlet opening 4a and the seal 22, it is proposed that the radial distance 34c of the circumferential surface 4b to the longitudinal axis 12 in the sealing area 16 is smaller than or equal to the radial distance 34a, b between the inlet opening 4a and the sealing area 16. In particular, this also includes the collar 26, which is a taper of the clear width of the inlet 4a. A groove 36 is provided in the collar 26 for this purpose. This is shown in more detail 2a.
This makes it possible to completely empty a non-activated nozzle 2 after fire-fighting has been carried out. The longitudinal axis 12 runs horizontally. Due to the fact that the radial distance 34c, starting from the sealing area 16, via the radial distance 34b in the area of the groove to the radial distance 34a at the inlet opening 4a, becomes at least constant, but preferably larger, extinguishing fluid can flow out of the inlet opening 4a driven by gravity.
The groove 36 can be seen again in the sectional view according to
It is also possible to mount the valve stem 24 in the outlet 18 so as to be movable along the transverse axis 14, as shown in
With the aid of the nozzle shown, a dry-biased system can be protected from frost damage even after it has been activated.
2 fire-fighting nozzle
4 inlet
4
a inlet opening
4
b inner lateral surface
6 fitting
8 pipe
10 clamp
12 longitudinal axis
14 transverse axis
16 sealing area
18 outlet
18
a nozzle outlet
20 nozzle insert
22 gasket
24 valve stem
26 collar
28 spring
30 glass barrel
32 clearance
34 radial clearance
36 groove
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2020 112 805.3 | May 2020 | DE | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2021/058986 | 4/7/2021 | WO |
