DE102013020631B4 - Extinguishing nozzle head - Google Patents

Abstract

The invention relates to an extinguishing nozzle head for generating a mist of extinguishing fluid with a housing (11) in which an inflow opening (12) receiving the extinguishing fluid is provided, having a flow (13) arranged in the housing (11) and communicating with the inflow opening (12). 12), nozzle channels (14, 15, 16) extending from the flow, each having at least one nozzle opening (17, 18, 19) releasing a mist of extinguishing fluid, the nozzle channels being opposite a central axis (26) of the nozzle Housing (11) are executed incidentally, wherein circumferentially nozzle channels are arranged summarized at a level to a row of nozzles, wherein at least two rows of nozzles are provided, wherein at least one row of nozzle nozzle channels (14, 15, 16) seen from the top of the extinguishing nozzle head above a another row of nozzle channels (14, 15, 16) is arranged. It is provided that the upper row of nozzles has substantially at least twice as many nozzle channels as the lowermost row, and that the nozzle channels (14, 15, 16) of the uppermost row substantially at a right angle to the central axis (26) of the housing (11 ) are arranged.

Description

The invention relates to an extinguishing nozzle head for generating a mist of extinguishing fluid with a housing in which an extinguishing fluid receiving inflow opening is provided with a flow arranged in the housing, which is connected to the inflow opening, wherein the flow outgoing nozzle channels are provided, the each having at least one nozzle opening releasing a mist of extinguishing fluid, wherein the nozzle channels are designed incidentally with respect to a central axis of the housing, wherein circumferentially nozzle channels are arranged summarized at a level to a row of nozzles, wherein at least two rows of nozzles are provided, wherein at least one row of nozzles nozzle channels of seen from the top of the extinguishing nozzle head is arranged above a further row of nozzle channels.

Fire fighting with the help of water mist is well known. In this form of fire fighting extinguishing fluid, preferably water, finely dusted through a nozzle, so that the smallest water droplets with diameters between 10 .mu.m and several 100 .mu.m arise. These small water droplets are discharged from the extinguishing nozzle with the help of high pressure and directed to a source of fire. As a result, a strong cooling of the fire is achieved, whereby a good fire fighting is possible. In addition, with the help of the mist, an enclosure of the source of fire is possible, such that the oxygen supply of the fire is impaired.

Both in the design of the nozzles and the nozzle heads, great importance has been attached in the past to producing the mist with the aid of so-called nozzle inserts. In this case, nozzle inserts are screwed into extinguishing nozzle heads. The nozzle inserts have small nozzle openings through which the extinguishing fluid can escape. Upon exiting the nozzle opening, the extinguishing fluid is torn open, causing the mist droplets. However, the use of nozzle inserts is complex and expensive, so that one is looking for cheaper extinguishing nozzle heads.

Here is among others the EP 1 239 926 A1 to call. This describes a quenching nozzle head, wherein the nozzle openings are drilled by drilling into the extinguishing nozzle head. In order to produce an even, evenly distributed and fine mist pattern, it is proposed to arrange two concentric bores in succession in the direction of flow, so that the fluid jet emerging from a first bore and tearing therefrom strikes the wall of the second bore, which is to be achieved the mist is split even finer. The disadvantage here, however, that only a conical spray pattern can be generated by the concentric holes. It is also disadvantageous that significant kinetic energy is lost as a result of the impact of the fluid droplets on the inner wall of the second bore, and the spray jet only has a low penetrating force. This is especially critical for the deposition of flue gases.

From the DE 10 2008 021 925 A1 an extinguishing nozzle head is known in which spray nozzles arranged circumferentially to a row are each arranged perpendicular to the lateral surface of the spray head. This upper row of nozzles releases the extinguishing fluid onto an existing deflector, which redirects the extinguishing fluid and fuzzes it into a mist. Below the spray nozzles additional nozzles are arranged in a groove, which emits the extinguishing fluid in a spray angle away from the extinguishing nozzle head in the radial direction. The two streams cross near the deflector, increasing fogging and creating a conical nebula. The pressure of the extinguishing fluid is a pressure in the amount of 6 to 30, preferably above 10 bar, or 30 to 300 bar indicated. Again, it is disadvantageous that significant kinetic energy is lost by the impact of the fluid droplets on the deflector and the spray has only low penetration. This is especially critical for the deposition of flue gases.

From the DE 10 2011 102 693 A1 an extinguishing nozzle head is known in which a centrally directed downward nozzle and two rows of nozzles, each of which is designed to be incident with respect to the central axis of the extinguishing nozzle head, are provided. The angle of attack of the nozzles with respect to the central axis should be between 0 and less than 90 degrees, but optimally 20 to 70 degrees. The nozzle openings are arranged in circumferential groove-shaped flow channels, which have different dimensions in the longitudinal and transverse directions, whereby an asymmetric spray pattern is to arise. A similar structure is also from the WO 2004/094000 A1 known.

From the GB 1 432 497 A is a spray nozzle for use in connection with extinguishing hoses is known in which a plurality of rows of superposed holes are provided which act as nozzle channels and of which the uppermost holes perpendicular to the central axis of the spray nozzle and the underlying three rows at smaller angles than 90 ° to the central axis of the spray nozzle. The rows each have six holes.

All the above-mentioned embodiments, the difficulty inherent in the case of fire, the flue gases to beat down sufficiently if the Energy of the extinguishing fluid, for example, at low extinguishing fluid pressure is low. Furthermore, they are all connected in sections so that groups of extinguishing nozzle heads are always activated in the activation case.

Accordingly, the invention has for its object to provide a quenching nozzle head, in which in a particularly simple manner, a spray with high penetration even at low extinguishing fluid energy or at low extinguishing fluid pressure can be generated, which is just suitable for depositing flue gases at low fluid pressures ,

This object is achieved with a quenching nozzle head with the features of claim 1, and accordingly, the task is surprisingly solved, particularly surprisingly, by the fact that the upper nozzle row has substantially at least twice as many nozzle channels as the lowermost row, and in that the nozzle channels of the uppermost row are arranged substantially at a right angle to the central axis of the housing.

It has been found that particularly good firefighting results are achieved by such an arrangement and that particular results are achieved with regard to the deposition of flue gases.

An advantageous teaching of the invention provides that at least one recessed in the outer surface of the housing of the extinguishing nozzle head flow channel is provided, into which a nozzle channel opens and in which a nozzle opening is provided. This supports the formation of fog.

Furthermore, it is advantageous that a closure element can be arranged in at least one nozzle channel and / or flow channel, wherein a thread for receiving a threaded plug is preferably provided for the arrangement in the nozzle channel and / or flow channel. By providing closure elements, it becomes possible to generate the mist in a directed manner. In particular, in the case of the right-angled outer nozzle channels, it is advantageous, for example in the case of a wall insert of the extinguishing nozzle heads, to close certain areas, in particular the channels directed towards the ceiling of the room.

Another teaching of the invention provides that at least five nozzle channels are arranged to the bottom nozzle row. It has been found that such an arrangement is advantageous, particularly when the extinguishing nozzle head is used at low pressures, since this improves the formation of mist directly directed to the source of the fire.

A further teaching of the invention provides that a first row of nozzles is provided with at least one nozzle channel, which has a first angle relative to the central axis of the housing, that a second row of nozzles is provided with at least one nozzle channel, which above the first row of nozzles from the top of Extinguishing nozzle head is arranged seen from, and in which the nozzle channel with respect to the central axis of the housing has a second angle, that a third nozzle row is provided with at least one nozzle channel, which is arranged above the second nozzle row seen from the top of the extinguishing nozzle head, and in the the nozzle channel has a third angle relative to the central axis of the housing, that the first angle is smaller than the second angle and the second angle is smaller than the third angle, and that the third angle is substantially perpendicular to the central axis. This causes optimal fogging. It is additionally advantageous that the nozzle channels of the third row of nozzles are arranged radially offset from the second row of nozzles.

A further teaching of the invention provides that a movement element, preferably a piston, is provided in the inflow opening and / or in the flow, which in a first position the inflow opening and / or the flow against a flow of extinguishing fluid through the inflow opening and / or blocks the flow and releases in a second position the inflow opening and / or the flow for the flow of extinguishing fluid through the inflow opening and / or the flow. It is further advantageous that the movement element has a portion which remains in the second position in the inflow opening, wherein the portion particularly preferably has recesses for overflow through the extinguishing fluid. As a result, a secure closing of the extinguishing nozzle head or an optimal extinguishing fluid supply is ensured in a simple manner. The movement element makes it possible to activate only individual extinguishing nozzles.

A further teaching of the invention provides that the movement element has a receptacle for a triggering ampoule, and / or that the movement element has a recess for a sealing element, preferably an O-ring.

A further teaching of the invention provides that a triggering ampoule is provided, wherein triggering ampoule is preferably protected by a protective element provided on the housing against mechanical damage, wherein it is particularly preferably an integral part of the housing provided protective element formed of webs, which are connected to one another at an end point, which is provided as an abutment for the triggering ampoule. As a result, the trigger ampoule is easily protected against mechanical damage. If a movement element is provided as described above, then it is advantageous for a receptacle for the release ampoule to be provided on the movement element, preferably on its front side. The provision of a triggering ampoule allows for easy activation of the extinguishing nozzle head. The combination of trigger pulley and moving element, it is possible that only extinguishing nozzle heads are activated, in which actually the Auslöseampulle is activated by the heat. As a result, extinguishing water damage is minimized. The combination of a triggering ampule with a quenching nozzle head allows for a smaller tube width of the conduit system feeding the quenching fluid, since only the quenching nozzle heads activated by their triggering ampoule need to be supplied.

The extinguishing nozzle head has a housing with an outer surface.

Furthermore, the object of the invention is achieved by the use of an extinguishing nozzle head with the features of claim 11, that is, a previously described extinguishing nozzle head for generating a mist for fire fighting with a pressurized extinguishing fluid, the pressure between 4 and 16 bar. It has surprisingly been found that such use allows optimal fogging and thus optimal fire fighting.

The article will be explained in more detail with reference to drawings showing an exemplary embodiments. Showing:

1 a partially cutaway exploded view of the extinguishing nozzle head according to the invention

2 a detailed view too 1 , and

3 a plan view of the extinguishing nozzle head according to the invention.

1 shows an exploded view of a nozzle head 10 with a housing 11 in which an inflow bore 12 is provided as an inflow opening. Preferably, the extinguishing nozzle head 10 made of stainless steel, but may also be formed of other iron alloys as well as copper alloys. The inflow bore 12 opens in a distribution chamber formed as a flow 13 , Starting from the distribution chamber 12 extend nozzle channels 14 . 15 . 16 , The nozzle channels 14 . 15 . 16 open into nozzle openings 17 . 18 . 19 , The nozzle openings 17 . 18 . 19 are in flow channels 20 . 21 arranged, which are designed as holes.

The nozzle channels 14 . 15 . 16 are in rows of nozzles 30 . 31 . 32 arranged. The first row of nozzles 30 points opposite the central axis 26 an angle α. The second row of nozzles 31 has an angle β with respect to the central axis. The third nozzle axis 3 points opposite the central axis 26 an angle γ. The angles .alpha., .Beta.,. Gamma are in a relationship to one another, where .alpha. Is smaller than .beta. Small .gamma. According to the invention, γ is substantially 90 Degree.

At the rear end of the distribution chamber 13 closes the inlet hole 12 at. The inlet hole 12 surrounding part of the housing 11 is with a thread 22 Mistake. At the front end of the distribution chamber 13 is a receiving hole 23 provided, which at its front end designed as a holder bore 24 having. The bore serves to accommodate a trigger ampoule 25 in the assembled state (not shown) of the extinguishing nozzle head 10 also in the locating hole 23 is arranged. The receiving bore 23 is from Stegen 27 surrounded by openings between them 28 through which the heat of a fire to the trigger ampoule 25 can get. These openings 28 are how out 3 can be seen by drilling 29 formed, parallel to the mounting hole 23 in the case 11 are introduced. In this hole 29 is also the nozzle opening 17 of the nozzle channel 14 arranged. The bridges 27 form a protective element 33 for the trigger ampoule 25 ,

1 shows that the second and third row of nozzles 31 . 32 in the direction of the longitudinal axis 26 are arranged parallel to each other. 3 alternatively shows that the second and third row of nozzles 31 . 32 in the direction of the longitudinal axis 26 offset from one another.

The distribution chamber 13 expands starting from the inflow bore 12 on, in which the rear wall surface 34 the distribution chamber 13 fanning out conically. On the opposite side of the distribution chamber 13 closes the front wall surface 35 also conical to the receiving bore 23 out.

Within the inflow bore is a moving element 36 provided in the form of a piston. This piston 36 has a rear section 37 that has a diameter 38 having substantially the diameter 39 the inflow bore is identical, and a forward section 40 on, of a diameter 41 having substantially the diameter 42 the receiving bore 23 is identical. Furthermore, the rear section 37 a depression 43 on, which to its lateral boundary wall sections 44 that has recesses 45 are separated. Also on the back section 37 is a channel 46 provided in which a sealing element 47 , here in the form of an O-ring can be arranged. The transition from the back section 37 on the front section 40 via a conical section 48 , The conical section 48 It is essentially identical to the front wall surface 35 the distribution chamber 13 one. At the front end of the front section 40 is a hole 49 provided in the assembled state (not shown) of the extinguishing nozzle head 10 the trigger ampoule 25 is used.

Behind the piston 36 are in the mounted state (not shown) in the inflow bore 12 a sieve 50 against contamination / foreign body entry into the extinguishing head 10 and a clamping ring 51 for positioning the sieve 50 arranged. At the same time prevent sieve 50 and clamping ring 51 that the piston 36 from the inlet hole 36 for example, can fall out during assembly.

In the mounted, untripped condition is the trigger pulley 25 in the receiving hole 23 , The front end of the trigger ampoule 25 is located in the hole 24 , The rear end of the trigger ampoule is located in the bore 49 of the piston 36 , The trigger pulley thus forms the abutment for the piston 36 ,

The front section 40 of the piston 36 can be found in the mounting hole 23 , The rear section 37 is located in the inflow bore 12 , The compressible O-ring 47 is in the channel 46 arranged, with its outer wall against the wall surface of the inflow bore 12 pressed and sealed against the in the line (not shown) into which the extinguishing nozzle head is screwed, located extinguishing fluid from. Behind the rear section 37 is the sieve 50 and the clamping ring 51 arranged.

Due to the rising temperature in case of fire, the expands in the trigger ampoule 25 alcohol and will burst the glass of the trigger ampoule. As a result, the front abutment of the piston drops 36 away and the pressurized extinguishing fluid pushes the piston forward until the conical surface 48 of the piston comes to rest on the conical front wall surface. The rear section 37 of the piston 36 is still in this position in the inflow bore 13 , which continues as the leadership of the piston 36 serves. The extinguishing fluid now flows from the recess in the case of activation 43 through the recesses 45 that now has a connection between the inlet hole 12 and the distribution chamber 13 form, in the distribution chamber 13 one. From the distribution chamber 13 the extinguishing fluid flows at an angle of attack at an angle to the longitudinal axis 26 of the extinguishing nozzle head 10 through the nozzle channels 14 . 15 . 16 , The quenching fluid flows with laminar flow into the distribution chamber and from there through the nozzle channels 14 . 15 . 16 , Immediately after emerging from the nozzle openings 17 . 18 . 19 The laminar flow of the extinguishing fluid changes into a turbulent flow. The extinguishing fluid breaks into a turbulent spray and is, inter alia, via the flow channels 20 . 21 or through the hole 29 transported to the outside, where it forms a fog.

When wall mounting are in the extinguishing nozzle heads 10 in the flow channels 20 . 21 pointing in the direction of the ceiling, provided with threads (not shown) into which plugs (not shown) can be screwed.

Claims (11)

Extinguishing nozzle head for generating a mist of extinguishing fluid with a housing ( 11 ), in which a the receiving fluid receiving the extinguishing fluid ( 12 ) is provided with a in the housing ( 11 ) arranged flow ( 13 ), which with the inflow opening ( 12 ), wherein outgoing from the flow nozzle channels ( 14 . 15 . 16 ) are provided, which in each case at least one nozzle opening releasing a mist of extinguishing fluid ( 17 . 18 . 19 ), wherein the nozzle channels with respect to a central axis ( 26 ) of the housing ( 11 ) are arranged incidentally, wherein circumferentially nozzle channels are arranged summarized at a level to a row of nozzles, wherein at least two rows of nozzles are provided, wherein at least one row of nozzles nozzle channels ( 14 . 15 . 16 ) seen from the top of the extinguishing nozzle head above another series of nozzle channels ( 14 . 15 . 16 ), characterized in that the upper nozzle row has substantially at least twice as many nozzle channels as the lowermost row, and that the nozzle channels ( 14 . 15 . 16 ) of the top row substantially at a right angle to the central axis ( 26 ) of the housing ( 11 ) are arranged. Extinguishing nozzle head according to claim 1, characterized in that at least one in the outer surface of the housing ( 11 ) of the extinguishing nozzle head ( 10 ) is arranged recessed flow channel, in which a nozzle channel ( 14 . 15 . 16 ) and in which a nozzle opening ( 17 . 18 . 19 ) is provided. Extinguishing nozzle head according to claim 1 or 2, characterized in that in at least one nozzle channel ( 14 . 15 . 16 ) and or Flow channel ( 20 . 21 ) a closure element can be arranged, wherein preferably for the arrangement of the closure element in the nozzle channel ( 14 . 15 . 16 ) and / or flow channel ( 20 . 21 ) is provided a thread for receiving a threaded plug. Extinguishing nozzle head according to one of claims 1 to 3, characterized in that at least five nozzle channels are arranged to the bottom nozzle row. Extinguishing nozzle head according to one of claims 1 to 4, characterized in that a first row of nozzles with at least one nozzle channel ( 14 . 15 . 16 ), which is opposite the central axis ( 26 ) of the housing ( 11 ) has a first angle, that a second row of nozzles with at least one nozzle channel ( 14 . 15 . 16 ) is provided, which is arranged above the first nozzle row seen from the tip of the extinguishing nozzle head, and in which the nozzle channel ( 14 . 15 . 16 ) with respect to the central axis ( 26 ) of the housing ( 11 ) has a second angle, that a third row of nozzles with at least one nozzle channel ( 14 . 15 . 16 ) is provided, which is arranged above the second nozzle row seen from the top of the extinguishing nozzle head, and wherein the nozzle channel ( 14 . 15 . 16 ) with respect to the central axis ( 26 ) of the housing ( 11 ) has a third angle, that the first angle is smaller than the second angle and the second angle is smaller than the third angle, and that the third angle substantially perpendicular to the central axis ( 26 ). Extinguishing nozzle head according to claim 5, characterized in that the nozzle channels of the third row of nozzles are arranged offset radially with respect to the second row of nozzles. Extinguishing nozzle head according to one of claims 1 to 6, characterized in that in the inflow opening ( 12 ) and / or in the flow ( 13 ) a movement element ( 36 ), preferably a piston, is provided, which in a first position, the inflow opening ( 12 ) and / or the flow ( 13 ) against a flow of the extinguishing fluid through the inflow opening ( 12 ) and / or the flow ( 13 ) locks and in a second position the inflow opening ( 12 ) and / or the flow ( 13 ) for the flow of extinguishing fluid through the inlet ( 12 ) and / or the flow ( 13 ) releases. Extinguishing nozzle head according to claim 7, characterized in that the movement element ( 36 ) a section ( 37 ), which remains in the second position in the inflow opening, wherein the portion, particularly preferably recesses ( 45 ) to overflow through the quenching fluid. Extinguishing nozzle head according to claim 7 or 8, characterized in that the movement element ( 36 ) a recording ( 49 ) for a triggering ampule ( 25 ), and / or that the movement element ( 36 ) a recess ( 46 ) for a sealing element ( 47 ), preferably an O-ring. Extinguishing nozzle head according to one of claims 1 to 9, characterized in that a triggering ampoule ( 25 ), wherein triggering ampoule ( 25 ) preferably of one on the housing ( 11 ) provided protective element ( 52 . 27 ) is protected against mechanical damage, wherein it is particularly preferably an integral on the housing ( 11 ) provided protective element ( 33 ) formed from webs ( 27 ), which are interconnected at an end point which serves as an abutment ( 24 ) for the trigger ampoule ( 25 ) is provided. Use of an extinguishing nozzle head according to one of claims 1 to 10 for producing a fire-fighting mist with an extinguishing fluid under pressure, the pressure being between 4 and 16 bar.

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