DE20217652U1 - Sprinkler jet with integral release has a compact housing for a triple spray system and an external release for a membrane valve - Google Patents

Abstract

A sprinkler jet system has a compact housing for a triple spray system as well as an external release for a trapped gas volume which keeps a membrane valve pressed onto a central plug. The external release has a glass element which breaks at a set temperature, releasing the trapped gas and causing the membrane valve to open. The water inlet is secured to the housing and sealed using an O-ring and has an integral filter element to prevent particles blocking any of the three spray jets. The triple spray produces three water mist sprays which oscillate to provide a wide spread of water droplets.

Description

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Patent attorney and lawyer Günter Leinung

PA Leinung - Olvenstedter Str.15 - D-39108 Magdebur g

Applicant:

Hans-Joachim Herzog Neindorfer Strasse 53 39387 Oschersleben

Telephone 0391 / 7339433 Fax 0391/7392868 Email Leinung@t-online.de

Bank details

Dresdner Bank Magdeburg Account No. 0309418200 Bank Code 81080000

ID No.: DE 139 274

Triple nozzle with integrated excitation element

The invention relates to a triple nozzle with excitation element according to the preamble of claim 1.

Fires are extinguished by using extinguishing agents, whereby the extinguishing agents act physically or chemically on the respective combustion process and are intended to interrupt it. The physical state of most extinguishing agents is liquid and the extinguishing effect of an extinguishing liquid is based on the high capacity through which the

Temperatures in the reaction zone/fire zone are reduced. Even a relatively small amount of cooling increases the reaction rate to a very high degree and extinguishes the fire. In order to absorb a large amount of heat in the shortest possible time, it is necessary that the liquid extinguishing agent comes into contact with the combustion zone with as large a surface as possible.

In permanently installed extinguishing systems, e.g. sprinkler systems, water flowing out under pressure is atomized via nozzles and exits the nozzles as a water mist. So-called two-fluid nozzles are used, as described in DE 43 35 827 Al, in which a high-speed gas breaks up a liquid jet so that the liquid jet is divided into individual water droplets, which is intended to atomize the water jet.

This process and the nozzles used require considerable financial and manufacturing requirements and are not universally applicable.

The problem of spraying extinguishing agents is also addressed in DE 44 07 780 C2, which is used to develop a spray nozzle for producing a double spray cone. The spray nozzle, which is installed radially in a pipeline, consists of a housing with a pressure chamber built into it and flow bodies inserted into the pressure chambers, which are designed in such a way that the extinguishing agent emerges in a nebulized form from the outlet side of the spray nozzle.

To increase the effect of the mist of the extinguishing agent, preferably water, a triple nozzle, as described in DE 196 45 004 A1, has already been proposed. The structural design of this swirl nozzle results in a much higher atomization of the extinguishing agent such that a triple water mist emerges on the outlet side of the swirl nozzle.
Special control devices are required to control these nozzles, which significantly increases the manufacturing and especially the maintenance costs of fire-fighting systems.

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The object of the present invention is to develop a swirl nozzle with an excitation element which is designed and constructed in such a way that it can be put into operation independently of central fire alarm systems and the disadvantages of the known solutions are avoided as far as possible.

According to the invention, the object is achieved with the features of claim 1.
Advantageous embodiments and special designs are the subject of the subclaims.

Thus, a triple nozzle with an exciter element was created, in which the triple nozzle and the exciter element are arranged in a housing in such a way that the triple nozzle is exchangeably fastened centrally in the housing with its water inlet side, while the exciter element is arranged circumferentially in a receptacle of the housing.

The invention also includes the provision of a diaphragm valve in the housing, which is functionally connected to the triple nozzle and the excitation element.
It is also inventive that the triple nozzle and the excitation element are connected to a connecting piece via the housing, wherein the connecting piece is designed in such a way that supply lines can be connected to it, by means of which the extinguishing agent, here water, is supplied to the triple nozzle.

It is also within the scope of the invention that a jacket filter is arranged in the connection piece on the water inlet side and that the housing is designed with water passage openings.
Another essential feature of the invention is that a pressure chamber is present circumferentially between the diaphragm valve and the receiving bore of the housing, which is functionally connected to the excitation element via a bore.

The diaphragm valve itself consists of a support body, which is surrounded by a diaphragm. The diaphragm valve is designed in such a way that when the triple nozzle is in the resting position, it shuts off the water supply to the triple nozzle and, on the other hand, when a fire breaks out and the valve is activated, the extinguishing water is directed to the triple nozzle via the diaphragm valve. This happens via the openings provided between the support body and the diaphragm of the diaphragm valve.

The advantages of the new solution are that fire protection systems equipped with these triple nozzles can be activated individually via the respective activation element, so that fire fighting can be carried out in a targeted manner without the uncontrolled discharge of extinguishing water causing additional damage.

This is prevented in particular by the design and function of the triple nozzle, since the water does not come out of the triple nozzle in the form of a jet, but rather in the form of a water mist in pulses. This is achieved by means of a water-air mixture applied to the respective nozzle.

This creates alternating mixing zones of the spray mist produced, which together form a spray cone. The water droplet sizes in this spray cone are in the diameter range of less than 0.1 mm. The alternating penetration of the hollow cone spray jets creates a very fine water mist, and the impulsive addition of air causes a flake-like water mist to emerge from the triple nozzle, which spreads in pulses, thus enabling effective fire fighting with low extinguishing water consumption.

When it is put into operation, the triple nozzle produces three spray water cones, with the outer hollow cone vibrating in alternating sequence from the outside to the inside. The inner hollow cone vibrates constantly from the inside to the outside and back, while the middle hollow cone vibrates between the outer and inner hollow cones and causes the entire water mist of the triple nozzle to be thrown out more, so that throw distances of up to 6 m can be achieved at a pressure of 5 bar.

Another significant advantage of using the triple nozzle with integrated excitation element is that fire detection and extinguishing equipment are integrated in one component. The fire detection in the form of the excitation element and the extinguishing equipment in the form of the triple nozzle.

The invention will be explained in more detail with the following exemplary embodiment. The accompanying drawing illustrates the arrangement and structure as well as the

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Functional interaction of the triple nozzle with excitation element in a sectional view.

As can be seen from the drawing, the triple nozzle 1 with the activator element 3 is designed as a compact structural unit, in such a way that the triple nozzle 1 is arranged centrally in a recess in the housing 4 and the activator element 3 is arranged circumferentially in a recess in the housing 4. The triple nozzle 1 with the activator element 3 is connected via the housing 4 to the connector 5, which is designed on the water inlet side so that supply lines for extinguishing media can be connected. This can be done via threaded connections or clamp connections or couplings.
A jacket filter 6 is provided in the connection piece 5, which is designed with a mesh size to retain any impurities that may be present in the extinguishing water, so that these cannot reach the triple nozzle 1, thus preventing malfunctions of the triple nozzle 1 caused by contamination. To prevent the escape of extinguishing water via the connection point from the connection piece 5 to the housing 4, a sealing ring 17 is provided between the two parts, which is received in a circumferential groove in the housing 4.

Furthermore, a diaphragm valve 2 is arranged in the housing 4, which rests on the right-hand side on the wall of the housing 4 and on the left-hand side on an intermediate piece 18, which is then connected to the triple nozzle 1.

The diaphragm valve 2 consists of a support body 12, the diaphragm 13, which circumferentially surrounds the support body 12, wherein passage openings 14 are provided between the outer circumference of the support body 12 and the inner wall of the diaphragm 13.

In the housing 4 there is also a pressure chamber 7 which is formed between the outer circumference of the membrane 13 and the inner wall of the bore of the housing 4. A bore 8 opens into this area of the pressure chamber 7, which creates a connection between the pressure chamber 7 and the receptacle for the excitation element 3 and establishes the functional connection between the excitation element 3 and the membrane valve 2.

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The activation element 3 is designed as a commercially available sprinkler element and serves in the broadest sense as a fire detection device and at the same time as a functional element for activating the triple nozzle 1, which is described in more detail below.

The triple nozzle 1 arranged in the housing 4 on the water outlet side consists of the individual swirl pieces 9, 10, 11 joined to one another, whereby the inner swirl piece 9, the middle swirl piece 10 and the outer swirl piece 11 are designed and joined to one another in such a way that the supplied extinguishing water exits via the mouthpiece and the outlet openings of the triple nozzle 1 in a nebulized form, thereby forming three spray water cones.
The triple nozzle 1 is connected to the housing 4 via corresponding fastening screws and a seal 17 provided in the housing of the triple nozzle 1 prevents the escape of extinguishing water between the housing 4 and the triple nozzle 1.

When installed, the triple nozzle 1 and the activator element 3 are connected to the connector 5 via the housing 4. A connecting line for the extinguishing water is connected to the connector 5, which is water-conducting, so that the interior 16 of the connector 5 is filled with water and water is constantly present at the diaphragm valve 2.

If a fire breaks out and a certain temperature is reached, a glass part provided in the excitation element 3 is destroyed and the pressure in the pressure chamber 7 is released by a pressure equalization via the bore 8 to the excitation element 3, which results in the membrane 13 lying circumferentially against the inner wall of the housing 4 and thereby exposing the passage openings 14 between the support body 12 and the membrane 13. The water now reaches the triple nozzle 1 via the openings 15 in the housing 4 via these passage openings 14, is guided into the individual swirl pieces 9, 10, 11 and then, as already described above, exits the triple nozzle 1 in a nebulized form.

Claims (7)

1. Triple nozzle with integrated exciter element for use in fire-fighting systems, characterized in that the triple nozzle ( 1 ) and the exciter element ( 3 ) are provided in the middle and on the water outlet side of a housing ( 4 ), and a diaphragm valve ( 2 ) and an intermediate piece ( 18 ) are also arranged in the housing ( 4 ), wherein the triple nozzle ( 1 ) and the exciter element ( 3 ) can be connected to form a connecting piece ( 5 ) via the housing ( 4 ), and the connecting piece ( 5 ) is designed with connections for receiving supply lines carrying extinguishing media. 2. Triple nozzle according to claim 1, characterized in that the triple nozzle ( 1 ) consists of individual swirl pieces which can be fitted into one another, an inner swirl piece ( 9 ), a middle swirl piece ( 10 ) and an outer swirl piece ( 11 ). 3. Triple nozzle according to claims 1 and 2, characterized in that a pressure chamber ( 7 ) is provided between the membrane ( 13 ) of the membrane valve ( 2 ) and the inner wall of the housing ( 4 ) and a bore ( 8 ) provided in the housing ( 4 ) connects the pressure chamber ( 7 ) with the excitation element ( 3 ). 4. Triple nozzle according to one of claims 1 to 3, characterized in that a jacket filter ( 6 ) is arranged in the interior ( 16 ) of the connecting piece ( 5 ). 5. Triple nozzle according to one of claims 1 to 4, characterized in that the housing ( 4 ) is formed with openings ( 15 ). 6. Triple nozzle according to one of claims 1 to 5, characterized in that the excitation element ( 3 ) is designed in the form of a sprinkler element. 7. Triple nozzle according to one of claims 1 to 6, characterized in that sealing rings ( 17 ) are provided at the connection points of the triple nozzle ( 1 ) to the housing ( 4 ) and of the housing ( 4 ) to the connection piece ( 5 ).