DD233490A1 - METHOD AND DEVICE FOR APPLYING A LUBRICANT - Google Patents

Abstract

The invention relates to a method and a device for applying a fire extinguishing agent to a fire by spraying or Zerstaeuben. The aim is to significantly expand the field of application of the known methods and devices, to increase their reliability and to reduce their effort. As little extinguishing agent as possible should be used and distributed in a large radius despite the high degree of obstruction of the objects to be protected. Furthermore, the pressure for applying the extinguishing agent should be substantially reduced and the necessary equipment and facilities easier than before. According to the invention, the extinguishing agent is sucked into a diffuser with the aid of an inert propellant gas. The device consists of a Duese, at the Einschnuerung followed by a short diffuser. Within the first third of the diffuser there is an admixing device connected to the extinguishing agent holder. figure

Description

lower pressures for the application of the extinguishing agent manage as they were required in the previous process. The funds required to carry out the method should be easy to produce, or should be used in particular for pressure generation such means that are generally available in production or other facilities.

According to the invention the object is achieved in that the extinguishing agent is sucked by means of an inert propellant gas in a diffuser.

In cases where water vapor is present in the immediate vicinity of the objects to be protected, it is advantageous to use water vapor as blowing agent. This is for example in steam heated systems, eg. As paper machines of the case.

The pressure of the inert propellant gas is advantageously 1.5 to 2.0 bar.

The device according to the invention is a nozzle, at the constriction of which a short diffuser adjoins. The length of the diffuser corresponds approximately to its smallest diameter. Within the first third of the diffuser there is a mixing device connected to the extinguishing agent container.

The admixing device may consist of bores inserted radially shortly after the nozzle-like constriction and opening into a ring conduit enclosing this area in an annular manner and connected to the extinguishing agent container. The

Opening angle of the diffuser is about 8 °.

The inert propellant gas is injected into the device at a pressure of about 1.5 to 2.0 bar. It absorbs on the basis of the known design principle of a spray nozzle, which is part of the device, the extinguishing agent. In the diffuser, propellant and extinguishing agents mix and form a dense mist immediately after exiting the relatively short diffuser which rapidly occupies a very large volume in relation to the size of the apparatus and thereby also reaches heavily obstructed areas of the object to be protected. One can imagine that the inert propellant because of its kinetic energy, the extinguishing agent distributed in a large radius.

The excellent extinguishing effect of the method is also based on the fact that the action of the extinguishing agent is still supported by the inert gas used as a propellant, which displaces the air and thus the oxygen from the environment of the source of the fire. Therefore, the method according to the invention comes with ensuring a very high extinguishing effect with very little extinguishing agent and also with a relatively low pressure of the inert propellant gas. As a result, the damage caused by the deletion process is much lower than was previously the case in the known extinguishing method. Very advantageous in this context, the extremely low extinguishing time despite the low extinguishing agent requirements. An empirical value states that in certain installations and facilities within a period of three minutes, a fire must be extinguished, if at the facility or device is not a total loss occur. This critical time is even undercut by the inventive method in a meaningful attachment to selected locations of the plant or device.

Finally, the structurally extremely simple device should be highlighted as an advantage. With low material and manufacturing costs, the device can be produced in any workshop. It does not occupy a large space and can thus be installed in any location with no problems even in systems with a high degree of obstruction.

embodiment

Below, the invention will be explained in more detail by way of example. The accompanying drawing shows the device according to the invention.

The device was made of a tube 1 with an inner diameter d! manufactured. The tube 1 was drilled from one side to a diameter d ₂ , wherein at the inner end of the bore by the tool used, a continuous transition from the diameter d ₂ was realized to the inner diameter di, thereby forming a nozzle-like constriction

2 made. The position of the constriction 2 in the interior of the tube 1 was chosen so that approximately one of the inner diameter d! corresponding length I of the tube 1 with the inner diameter di remains. This, the bore opposite end of the tube 1 has been worked up to constriction 2 conical, wherein the cone angle Na in the present example is 8 °. This results in this end of the tube 1, a diffuser 3 with an inner diameter d ^ corresponding to the smallest diameter and a largest diameter d _3rd At a distance of V31 from the constriction 2 eight radial holes 4 are introduced into the diffuser 3 in the present example. They are on the outer shell of the diffuser of a diffuser

3 in this area tightly enclosing ring line 5 sealed against the atmosphere. The ring line 5 is connected to an intake pipe 6, which opens into an extinguishing agent container, not shown in the present drawing. Now, if the cylindrically drilled end of the device connected to a steam line and the water vapor fed about 1.5-2.0 bar in the device, the water vapor sucks the extinguishing agent in the diffuser 3, mixes with the extinguishing agent and distributes it in the form fog as already described in the environment of the device.

Claims (5)

Claim: 1. A method for applying an extinguishing agent to a fire by spraying or atomizing, characterized in that that the extinguishing agent is sucked by means of an inert propellant gas in a diffuser. 2. The method according to claim!, Characterized in that water vapor is used as the inert propellant gas. 3. The method according to claim 1 and 2, characterized in that the pressure of the inert propellant gas is 1.5 to 2.0 bar. 4. A device for applying an extinguishing agent to a fire by spraying or atomizing, characterized in that the device consists of a nozzle, after the constriction (2) is followed by a diffuser (3) whose length is about its smallest diameter, d. H. the diameter of the constriction (2) corresponds to the nozzle and in the first third of its length there is a mixing device connected to the extinguishing agent container. 5. Vorrichtun according to claim 4, characterized in that the admixing device radially into the diffuser (3) introduced bores (4) which in a the diffuser (3) in this area annularly tightly enclosing and connected to the extinguishing agent container ring line (5 ). For this 1 page drawing Field of application of the invention The invention relates to a method and apparatus for applying a Lözusitteis to a fire by spraying or atomizing. Characteristic of the known technical solutions In order to achieve a high extinguishing success with economical use of extinguishing agents, the extinguishing agents are sprayed or atomized. As a result, a large volume is filled with extinguishing agent in a short time and kept the damage caused by the extinguishing agent in limits. For spraying water mainly Duke nozzles are used. Due to a special structural design of the interior of the nozzle, the water jet experiences a swirl shortly before it leaves this nozzle. As a result of this twist, the water jet breaks apart shortly after exiting the nozzle and forms a mist. The disadvantage of the duke nozzle is that a relatively large amount of extinguishing agent is required to produce the mist. For certain applications, such as extinguishing equipment for relatively large plants or machines that are to be protected in the event of fire extremely fast and reliable against fire spread and where the extinguishing agent must not cause any significant damage, Duke nozzles are not suitable. In addition, the achievable by them degree of nebulization or atomization is still too low. Therefore, a relatively large number of nozzles would have to be arranged on very large systems or machines, which is often not possible due to the very high degree of locking that such systems or machines, for example paper machines, have. At least in such cases, it will be extremely difficult to extinguish incipient fires which may occur in internal or in housing-concealed areas of such machines. In order to guarantee a minimum extinguishing success must therefore be provided in a very short time a high supply of extinguishing agent, which is associated with a considerable technical effort. In many cases, after the use of such an extinguishing device, the plant or machine unusable due to the large extinguishing agent damage. For fire fighting in large plants and in large spaces, for example, 'goods houses, sprinkler systems are used. Several sprinkler spray heads are usually installed in the ceiling area of the rooms. The spray heads are each connected to high pressure extinguishant supply lines. After the safety device of the spray head has responded, the extinguishing agent exits and is atomized by impinging on the baffle plate. Also in this method, applying the extinguishing agent as finely dispersed as possible on the Brandhert, the requirement for extinguishing agent is very high, which can lead to high water damage in the event of a fire. In addition, impinging on the baffle plate extinguishing agent jet is only insufficiently atomized, so that as in the o.g. Duke-nozzle obstructed area of the objects to be protected can not be reached. Essentially, only those areas are protected, which are hit by the free fall of the extinguishing agent droplets. Another disadvantage is the relatively high technical complexity required to produce the extinguishing agent pressure. Both technical solutions are thus, despite their great technical effort, which is required for both their installation as well as to ensure their function, for certain applications can not be used. For firefighting high-quality equipment or objects in relatively small spaces are used methods in which an inert gas is applied as an extinguishing agent on the fire. The effect of this extinguishing agent is based on the displacement of atmospheric oxygen from the environment of the source of the fire. At least as much inert gas, ζ. As CO2, are used, that the content of atmospheric oxygen reduced by about 50%. This method has the advantage that the extinguishing agent spreads rapidly throughout the room and even with a high degree of locking all areas de? -I ^s protective object 31 easily. However, this assumes that it is relatively small, mthr or less closed spaces, for example, housed in cabinets equipment. If this is not the case, the gas spreads and can not be effective in the desired manner to the source of fire. This method is therefore not suitable for firefighting "installations and objects in large rooms. Object of the invention The aim of the invention is a method and a device for applying an extinguishing agent, the scope of which is significantly expanded. At the same time a much more reliable fire fighting should be ensured at the same time as it was possible with previously common methods or devices. Furthermore, it is the object of the invention to significantly reduce the effort required to carry out the method of equipment technology compared to known devices. Explanation of the essence of the invention The invention has for its object to develop a method and a device that distribute relatively little extinguishing agent in a short time in a large radius in more or less obstructed areas within the perimeter, nhnfi hate Has nnsrhmittftl in Hip I Imnehi inn <ant «/ Oirht Pia hoi οπΙΙαπ Hoe Warfahran 1 » r> A h; »v / m -nnU · ·% *. »«: + ... _nn «« 4-i: _M u