SK50212014U1 - Method of fire ventilation function test and the device for thereof - Google Patents

Abstract

A non-toxic aerosol generator from the solid and gaseous phase simulating the combustion fumes, the component (2) of which is activated is then placed in the test area, followed by the propagation of the aerosol cloud and the evaluation of the functionality of the fire ventilation. The aerosol is a mixture based on potassium carbonate, potassium bicarbonate, carbon, carbon dioxide, water vapor, nitrous gases, nitrogen and ammonia, developed at a temperature of 600 to 1300 ° C in an amount of 3 to 100 m 3 / s, while the devices under test are in operation. heat and smoke removal. The apparatus includes a generator with containers (1) containing the composition (2) and a firing device (3) housed 4 to 10 in the bed (5) of the racks, mounted 1 to 20 in the bath (11) and covered with perforated lids (9). The bath (11) is preferably mounted on the vehicle support structure (14).

Description

Method for verifying the functionality of fire ventilation and equipment for carrying out the method

Technical field

The technical solution concerns fire safety and fire technology. A new method for verifying the functionality of fire ventilation is proposed and a device specifically configured to carry out this method of verifying the functionality of fire ventilation.

BACKGROUND OF THE INVENTION

The fire safety of large complexes, such as production facilities, industrial and non-industrial halls, motorway and road corridors, metro and other construction facilities, is determined primarily in theory, by calculating the design of their construction, based on scientific and technical expertise. The project of fire safety of buildings sets requirements for the structural design of buildings, used materials, means of protection against the occurrence and spread of fire. There are also intended means of detecting possible fire, means of fire ventilation of the object, air conditioning, escape routes and others. The basic fire safety equipment includes a device for heat and smoke removal, ie fire ventilation. Unfortunately, the project does not always take into account all the real hazards, sometimes the project is not precisely followed, sometimes the quality or maintenance of fire ventilation is not adhered to, and in other cases unexpected situations may arise that are solved only during construction. For these reasons, it is necessary to carry out tests to verify the functionality of fire ventilation before operation during operation.

At present, tests to verify the functionality of fire ventilation in buildings and line constructions are carried out so-called. performance tests. Here, the design parameters of the fire ventilation equipment are verified by physical measurements with anemometers, especially the speed and direction of the air flow in the test area over time. This method does not use special testing equipment in addition to measuring instruments.

As another method of verifying the functionality of a fire ventilation system, a method shall be used in which a real smoke generator similar to the actual smoke in a fire is placed in the test area, monitoring the movement and concentration of the smoke produced during operation. Real smoke is usually obtained by burning gasoline and / or diesel, solid combustible materials and, optionally, other combustible materials known as conventional materials burning in fires.

The advantage of this method is that it allows visualization, that is, a visible record with the possibility of monitoring and viewing the flow of flue gases and also gives the possibility of measuring the optical density of the smoke and thus monitoring the stratification of the smoke. Performing these visualization tests is very important, as they quite reliably enable the assessment of possible threats to the lives of people and give accurate values for software and hardware modifications to fire ventilation. This method is mainly used in tunnel constructions where people are most at risk of combustion products, be it transverse or longitudinal ventilation. A considerable disadvantage of this method is the formation of high temperature and toxic combustion products, which limit the possibility of taking measurements and the necessary records and endanger the persons present. The worst, at higher concentrations of lethal combustion products are generally known carbon dioxide (CO2), carbon monoxide (CO) and hydrogen cyanide (HCN), and all of these substances are also produced by the above method. Persons carry out these tests and possibly other persons have limited access to and movement in these areas during the tests and must be equipped with appropriate personal protective equipment, such as fire suits, masks, etc., which make the tests more expensive. The huge disadvantage of this method is that the high temperatures accompanying the combustion and / or the aggressive combustion products can cause the destruction of building structures and / or degrade the surface finishes and technological equipment of the buildings, contained brands, air conditioners, electronic systems, measurement and control elements, which could be hundreds of thousands of euros. This method uses simple tanks or baths, fully or partially flammable, as smoke evacuation equipment.

A variant of the method described in the previous paragraph is the method prescribed in RVS Directive 09.02.31, applicable in Austria, for verifying the functionality of ventilation in tunnel construction. Hot smoke, obtained by burning 51 petrol or 201 diesel on a 1m surface in a steel vessel, produces hot smoke, the passage of which is recorded in the test area for video recording, measuring the optical density of the smoke at different heights. During the operation of the included air handling equipment, the gas exchange and polluted air exchange time is monitored and finally evaluated, depending on the volume exchange of air masses and the optical density of the smoke. Depending on the results of the test carried out, the fire ventilation parameters on the air handling equipment contained therein are then set and the dispatchers are acquainted with the expected course of a real fire. This methodology does not capture any fire in terms of heat output or smoke production, mainly due to non-compliance

-3 of the desired amount of smoke produced in m / s. In the case of a car fire, 20 m ³ / s of smoke is generated, in the case of a medium-sized vehicle fire 50 m ³ / s of smoke and in the case of a truck fire 80 to 100 m ³ / s of smoke. In addition to the fact that the amount of smoke is not simulated in a real fire, this test also produces toxic and aggressive gaseous combustion products that degrade the tunnel's technological equipment and require repair and replacement, as well as the need to clean the tunnel space. high costs, as well as the necessity of long-term shutdown of tunnels and complicated transport and transportation.

Another method uses so-called. cold smoke. As a source for the monitored cloud is used common smoke, or only water vapor is used. The smoke product is a gas mixture. Also, water vapor is only a gas phase. In both cases, the resulting cloud is based on only harmless gaseous substances and is visible. The advantage of this method is the absence of toxic fumes and the possibility of recording and observing the movement of the developed cloud. However, the dynamics of the actual smoke behavior in terms of stratification cannot be achieved or approached, in particular due to the absence of thermal dynamics of solid particles whose presence would make it possible to measure the optical density comparable to that of a real fire. The consequence of this is that it is impossible to fully assess the proper functioning of fire ventilation.

The essence of the technical solution

The above-mentioned disadvantages are largely eliminated by the technical solution. A new method of testing the functionality of fire ventilation is proposed by placing a nontoxic aerosol generator simulating a combustion flue gas having a predetermined number of folds in the test area, activating these components, and then monitoring the propagation of the nontoxic aerosol being generated, making a video and making measuring the values necessary to evaluate the functionality of the fire ventilation in a given space, and finally the measured measurements are compared with the values of actual smoke, for example, produced by the combustion of petrol and diesel measured in the test area. Based on the results, the functionality of the fire ventilation of the tested area is evaluated and this knowledge will be used to set up the fire alarm detectors, control units of the tested air-conditioning and smoke and heat removal equipment for retrofitting, building modifications, and others. As for the measured values,

- at least airflow velocity, temperature in the region of the aerosol generator, temperature in the region outside the generator, and time are measured.

The generator preferably develops a nontoxic aerosol formed at a temperature of 600 to 1300 ° C, consisting of a mixture of a solid and a gas phase, of which the solid phase is composed of particles of 1 to 5 µm based on potassium carbonate, potassium bicarbonate and carbon, and a gaseous phase. is a medium based on carbon dioxide, water vapor, nitrous gases, nitrogen and ammonia. This aerosol has extinguishing effects. It is nontoxic with respect to the content of possible toxic impurities below the standards laid down, and with stratification, density, mobility and visually and measurable values comparable to the actual smoke properties resulting from combustion of gasoline, diesel and solids of conventional fire-inducing materials such as paper, plastics and others. The high temperature of aerosol formation makes it possible to perform temperature measurements at the location of the simulated fire. High temperature occurs only at the generator site and here simulates the course of a real fire, where during the aerosol movement through ventilation systems no longer devastating value and does not devastate technological or construction equipment of the building. The stratification of the aerosol cloud, the way it is carried through the test area and the optical density values correspond to the smoke values of real fires.

Preferably, the non-toxic aerosol is generated in an amount fully corresponding to the production of actual smoke in the fire, i.e. 3 to 100 m ³ / s, the specific amount to be generated for a particular verification test being predetermined within this range. This will be done in particular depending on the design parameters of the fire ventilation for the test area, for example at the level of the highest permitted by the project or at a level close to these values.

Preferably, all of the following values are monitored during the test. It is the velocity of the aerosol cloud movement measured by monitoring the air flow including the aerosol contained, the temperature in the region of the aerosol generator and the space, and the stratification and dispersion of the aerosol cloud by measuring the optical density of the aerosol. Advantageously, a video recording indicative of the direction and flow of the aerosol particles as a function of the fire ventilation function is also produced simultaneously, and the exchange time of gases and polluted air as a function of the volume exchange of air masses and the optical density of the aerosol is measured.

Preferably, in the test area, optical testing is performed by video recording and / or measurement at different distances from activation, and at different heights the optical

-5 aerosol density. These measurements at different distances and at different height levels make it possible to monitor the movement and dispersion of the aerosol cloud generated.

If the test area is equipped with an air handling device, it is advisable that all or, depending on the purpose of the test, some of the air handling equipment of the area under test be put into operation during aerosol generation and aerosol tracing. The method is mainly intended to verify that the test area is equipped with sufficient ventilation equipment for smoke and heat removal and to test the quality of the functionality of these devices in the given areas. Alternatively, however, it is not excluded with its help to test areas that are not yet equipped with ventilation equipment, which may be the case, for example, in older buildings and in buildings with natural ventilation.

Preferably, the non-toxic aerosol generator is placed on at least one carrier, attached to or behind the vehicle, prior to activation of the contained composition, in a position and accessible to the surrounding space so that the aerosol being generated can freely spread to the surrounding space. As a rule, this propagation is in the form of a cloud that moves within the test area and is dispersed or removed therein by means of the air conditioning devices tested and / or natural ventilation. Then, when the dose is delivered to the site of activation, it is performed once or sequentially, the activation by launching. Activation may occur statically, i.e., leaving the aerosol source stationary at the site of activation, until the aerosol cloud is dispersed or removed. Preferably, especially for tests in tunnels and other long corridors, during and / or after activation of the compound, the vehicle may move within the test area, for example by moving through the test area, moving a moving video device in the region of the aerosol cloud. another vehicle with a video camera, namely a video recording enabling visualization of the test progress. This embodiment of the method is ideal for testing railway or road tunnels.

The technical solution also solves the construction of equipment suitable for carrying out the proposed method of verification of the functionality of fire ventilation according to the technical solution. The apparatus comprises a generator comprising containers of a non-combustible solid material, for example steel, with an internal cavity which are at least partially filled with a combustible composition. The essence of the new solution is that the containers form a source of nontoxic aerosol imitating the appearance, optical density, stratification and movement pattern of reliable combustion products, namely an aerosol consisting of 1 to 5 µm solid particles and nontoxic

-6gaseous substances. No cooler is included, except for the container, only the launcher is contained in the vessel and there is only free space in the vessels above the launcher composition. In order to produce a sufficient amount of smoke imitation for the purpose of the method, these containers are in a number of 4 to 10 pieces stored in at least one non-combustible solid material storage, for example steel, and provided here with a common perforated lid.

The container receptacle is preferably in the form of a stand, the upper part of which is designed as a receptacle for receptacles and below this receptacle there is a pedestal with at least one internal cavity for the necessary electrical elements of the firing device.

Preferably, the bed is provided with at least one aperture and the inner cavity of the pedestal is passable adjacent to the aperture, the pedestal having at least one element stabilizing its position relative to the mat. As an element for stabilizing the position of the stand against the support, for example, a support plate with holes and threads or fixing screws, or welded strips of material, an elongated and bent pedestal leg wall, a welded profile, and the like can be used.

Preferably, the rack of one or more is housed in a tub of a non-combustible solid material, for example steel, wherein the tub comprises at least a bottom and an all-round rim, wherein the rack is fixed, immovably fixed to the bottom of the tub. The bath forms a supporting base for the racks occupied or only some of them occupied by containers, allows transport to be folded to the place of use and possibly during use and can serve for any additional, flammable filling if required by the customer to increase the fire effect such as ethanol. The portion of the skirt on the one hand can be elongated and used to attach the tub with the stands and the folds instead of being used, for example on a carrier, as further exemplified.

The tub preferably comprises one to twenty racks, wherein at least some of the racks included have a bed completely filled with containers. The perforated lid mentioned above in the first paragraph of the description of the device may be of dimensions to cover all of the contained racks at once, or to cover each of the contained racks separately, or to cover groups of racks. Preferably, the racks are covered by a perforated lid one at a time, thus saving material in the case of incomplete occupation of the rack and facilitating the handling associated with the assembly of the individual elements of the device into a unit.

Advantageously, in particular, allowing the method to be carried out in tunnels, the bath is supported on a supporting structure of a movable means, for example a vehicle, at least in the area of the lid free from the surrounding space. A bath with stands and folds can thus be advantageously

-Ί Attach, for example, to a truck behind the car or to a special carrier directly on the car. In contrast to current methods, the device so constructed and arranged can be operated without danger by the driver present in the test area.

Preferably, the composition consists of a material which upon firing produces a nontoxic aerosol, the solid particles of which contain a mixture of potassium carbonate, potassium bicarbonate, carbon and whose gas phase comprises a mixture of carbon dioxide, water vapor, nitrous gases, nitrogen and ammonia. This material is already known and commercially available, but it has been produced and used to date for a completely different purpose, such as a fire extinguishing mixture.

The proposed technical solution according to the technical solution has advantages in that it simulates real smoke as it arises during fire, but it is nontoxic and does not cause destruction or damage of instrument and other equipment in the building by high heat. The simulation of real smoke from the burning of substances that are a common cause of fire, ie diesel, gasoline, paper, wood, solid fuels, plastics, and others, is perfect especially visually. An aerosol cloud is formed which, for the human eye and even the detection device, has the appearance of smoke in a fire, and which has the same stratification with respect to particle density, cloud shape, movement pattern and dispersion rate and rate. Said values can be visualized by video recording, with the possibility of subsequent and repeated viewing, and with the possibility to measure values such as optical density at different locations and heights and others. The levels of toxic impurities present are below the level of established toxicity standards and thus the aerosol can be considered non-toxic. Since the aerosol cloud is not toxic and during the test is still dispersed in the test area and removed by the air conditioning system, it is possible to carry out the fire on a stationary or moving vehicle with a driver without risk to human health and ideally take place during the test. tests for recording video, for example, from a vehicle following a compound vehicle. Using the proposed method and equipment it is possible to perform quality and safe testing of the functionality of fire ventilation without the need for subsequent replacement of these devices or other equipment of the test area, and also without the necessity of heavy cleaning of these equipment and test area. from operation. The method and the device according to the technical solution make it possible to determine in an optimal way the values to which a particular fire ventilation is to be set. It also allows dispatchers to become acquainted with the real fire, ie with the probable direction of fire spread according to the place of origin and

-8priebehom. With regard to the toxicity of substances, the concentration of toxic impurities ranges from 100 to 600 times lower than the permissible exposure limits. It is possible to develop an imitation of smoke according to the required power, at a precisely predetermined value within the range of 3 to 100 m ³ / s. Activation of aerosol formation can be performed manually or remotely by means of an electrical pulse. The method and equipment are suitable for use in any test area, but especially for road and railway tunnels, large building complexes, industrial and other halls, technological operations, and others.

BRIEF DESCRIPTION OF THE DRAWINGS

The technical solution is elucidated by means of the drawings, in which FIG. 1 is a perspective view of an exemplary device for verifying the functionality of a fire ventilation system according to the invention, FIG. 2 is a top view of the compound container itself; FIG. Fig. 3 is a cross-sectional front view of the container taken along the line A-A shown in the preceding figure; 4 shows a perspective view of the stand itself, FIG. 5 is a front view of a vertical longitudinal section through a rack filled with containers over the center of the containers, FIG. 6 is a perspective view of a bathtub filled with empty racks; FIG. 7 is a perspective view of the tub itself; FIG. 8 shows a demonstration of the function of the proposed device and the implementation of a method for verifying the functionality of the fire ventilation in a room equipped with a ventilation device with a fan; FIG. 9 shows a demonstration of the function of the proposed device and the implementation of a method for verifying the functionality of fire ventilation in a room with natural ventilation by means of skylights; FIG. Fig. 10 A, B, C shows the functioning of the proposed device and three demonstrative variants of the method implementation in the verification of the functionality of the fire ventilation in the tunnel by means of static compositions; 11 A.B, C shows the functioning of the proposed device and three demonstrative variants of the method implementation in the verification of the functionality of the fire ventilation in the tunnel by means of movable components.

Example

An example of the best embodiment of the invention is an apparatus for performing a method of verifying the functionality of a fire ventilation system with examples of its use and a procedure for carrying out the method of FIG. 1 to 11.

The apparatus for carrying out the method of verifying the functionality of the fire ventilation is based on the generator shown in FIG. 1. The generator contains a source of nontoxic aerosol, simulating fumes emitted in a fire, which forms

9 containers 1 of non-combustible solid material. In this exemplary embodiment, containers of practical cylindrical shape, made of steel and having sufficient strength and mechanical resistance have been chosen. The inner cavity of the vessels 1 is partially filled with the cartridge, which is, as an aerosol source, a combustible composition 2. In addition to the component 2, each vessel also contains a firing device 3 with the necessary electrical accessories enabling firing. Above the composition 2 with the firing device 3, there is no more space inside the vessel 2, no cooler is present, the presence of which is considered necessary in the prior art. The arrangement of the containers 1 is well apparent from FIG. 2 and 3. As shown in FIG. 1, containers of 4 to 10 pieces are housed in bearings in the form of stands of non-combustible solid material. In this exemplary embodiment, the preferred number of containers 1 is selected in six pieces per rack, which is within the above range. The racks were made of steel for this exemplary embodiment, but other suitable material may be used to provide sufficient strength and mechanical resistance to the racks.

The arrangement of the racks and their occupation is readily apparent in Figures 4 and 5. The upper part forms a receptacle 5 for accommodating containers 1, having a box-like shape with a cut-out in the middle. Under this bed 5 is a pedestal 6, in this case arranged as a foot, but in another case it may have another suitable shape. The pedestal 6 is hollow, its inner cavity has dimensions and shape to accommodate the necessary accompanying electrical elements of the firing device, in particular electric conductors 4. The cutout in the middle of the bed 5 is arranged as an inlet opening 7 into the cavity of the pedestal 6 which is passable following this opening 7 The pedestal 6 is provided with at least one element stabilizing its position relative to the support, in this case a support plate 8 formed at the bottom. Each stand is provided with a screwed perforated lid 9 covering the containers 1 and preventing their unwanted release during transport to the place of use and during development aerosol and also prevent unwanted premature damage to the firing device 3 and possibly contained conductors 4. The perforation of the lid 9 forms passages for escaping the aerosol being generated from the containers 1 into the space and forming an aerosol cloud. The containers 1 can be placed in the rack 5 with the boxes 10 in which they are supplied, or the boxes 10 can be filled with the containers 1 with the component 2 separately prepared in advance, their presence facilitates handling of dose counting, filling the racks and cleaning used containers 1 and residual waste after completion of the tests.

The stands are numbered from one to twenty placed in a tub 11 of a non-combustible, sufficiently solid material. In this exemplary embodiment, the bath 11 is made of steel. The basin 11 has a bottom 12 to which all the racks contained are fixed, immovably fixed by conventional means of connection, such as screws, rivets, welds. Around the bottom 12 of the tub 11, an upwardly extending edge rim 13 is formed, preventing dropping of possibly broken pieces of material and allowing the location of additional fillers of the ethanol type and others according to the customer's request, for example to increase the fire effect. If a wire launcher 3 is used, the tub 11 may have openings 7 for the electrical conductors 4, these openings 7 being disposed so as to correspond appropriately to the cavities of the pedestals 6 and the openings 7 of the rack beds 5. Several racks 11 with racks may be used for a single test, depending on the calculated dose requirement of Compound 2. Of course, with respect to the number of containers 1 in each rack, it is of course considerably more economical for the bed 5 to preferably be filled with the entire containers 1, possibly. the number of containers 1 collected in one rack, with a greater number of unused racks than to evenly but incompletely occupy an unnecessarily large number of racks and to provide perforated lids 9.

The sump 11 may be mounted with one or more of the support structure 14 of the movable means, for example a vehicle, in a position and location of the vehicle selected such that at least the area of each lid 9 contained remains free from the surrounding space throughout the test. it is necessary to avoid the formation of a cloud from the aerosol being generated. The location is optimally by means of a special supporting structure 14 tailored for this purpose and fixed to the rear of the car, but other suitable support means, such as a roof rack on the vehicle, a trailer, a hull and the like can be chosen. The angular circumferential shape of the tub 11 and the other elements mentioned above is not a requirement.

Component 2 is a non-toxic aerosol generating material, the particulate matter of which contains a mixture of potassium carbonate (K2CO3), potassium bicarbonate (KHCO3) and carbon (C), and whose gas phase contains a mixture of carbon dioxide (CO2) water vapor (H2O) nitrous gases (NO _X ), nitrogen (N) and ammonia (NH4). For example, a mixture of the following composition is well suited to this material:

% wt. in a mixture of potassium perchlorate (KCIO4) 20 to 26 potassium nitrate (KNO3) 50 to 60

-11 epoxy resin bonding component, hardener up to 23 0.8 to 1.2

The abovementioned quantities and types of substances are understood to be materials available on the market, i.e. with a technical purity of about 99%, so that, in addition to the named substances, a small amount of impurities may also be present. The aerosol generated by the firing of this mixture can be characterized as unhealthy to harmful, but this harmfulness does not reach the degree that it can be considered toxic

The device is designed for a new method of verification of the functionality of fire ventilation according to the technical solution. In the following, an exemplary embodiment of tests with this method is described. The operation of the device and the implementation of the method are shown in Figures 8 to 11.

Preparation for carrying out the method shall include at least an examination of the design documentation of the test area, identification of the type, number and location of ventilation, heat and smoke and other equipment in the test area, detection of natural ventilation elements, identification of shape, dimensions and materials in the test area. design parameters of fire ventilation. Furthermore, this preparation includes the placement of the relevant sensors and gauges in the test area, including any video cameras 15 if not already installed. A device according to the invention is prepared in advance, equipped with the calculated number of containers 1 of composition 2. The non-toxic aerosol generator simulating the combustion products of which the components 2 are activated is placed in the test area, followed by the propagation of the aerosol being produced. it shall measure the values necessary to evaluate the performance of the ventilation in the space under consideration, and shall finally compare the measurements obtained with the values of actual smoke, such as from combustion of petrol and diesel, measured in the test area. Based on the results obtained, an evaluation of the functionality of the fire ventilation of the test area will be carried out. Measurement and evaluation shall preferably be carried out by means of modern science and technology, including data management and evaluation systems.

Upon firing, a non-toxic aerosol is generated in the generator at a temperature of 600 to 1300 ° C, the particular temperature values within this range being dependent in particular on the amount of material in the compositions 2, the particular composition of compositions 2, the presence and

- 12 amounts of oxidizing agents and, where appropriate, the presence of additional, inflammatory, temperature-increasing media such as ethanol in a bath 5. The aerosol generated from composition 2 consists of an aerosol cloud of a solid-gas phase, of which the solid phase is 1 to 5 6m * based on potassium carbonate, potassium bicarbonate and carbon, and the gas phase consists of a mixture of gaseous substances containing carbon dioxide, water vapor, nitrous gases, nitrogen and ammonia, and / or compounds thereof. The dose of Compound 2 is calculated so that the non-toxic aerosol is evolved at a rate of 3 to 100 m / s, and the specific aerosol evolution for a particular verification test is predetermined within this range according to the customer's desire, preferably according to the design parameters fire ventilation for the test area, for example at or near the upper limit of the maximum permitted by the project. During the test, the velocity of the air containing the aerosol, the temperature in the area of the aerosol generator and in the space, the optical density of the aerosol and possibly other measurable value in the tested space and possibly also in the inlets and outlets of air handling equipment are monitored. An important benefit of the technical solution is, among other things, the possibility to make a video of the direction and flow of aerosol particles directly in the area of the aerosol cloud edge depending on the fire ventilation function. The exchange time of gases and polluted air is also measured in dependence on the volume exchange of air masses and the optical density of the aerosol. Because the aerosol cloud has optical density, motion and dispersion properties comparable to actual fire smoke, the optical density of the aerosol is also measured at different height levels during the test area by video recording and / or measurement at different heights. The recorded video enables visualization of the course of the test, which can be used for evaluation of test results as well as for demonstrative purposes such as demonstration in training, for practical instructional training of firefighters and others.

If air conditioning devices are present in the test area, they are preferably in operation during aerosol generation and aerosol tracing. The method is solved for the purposes of tunnel and other corridor ventilation tests as follows. For large-size tunnels, halls and similar test areas, the non-toxic aerosol generator shall be placed 2 on at least one carrier attached to or behind the vehicle, in a position and accessible to the surrounding area, before the contained aerosol is activated, so that the aerosol being generated can freely spread into the surrounding space. The vehicle with component 2 is transported to the activation site of component 2 and then, during activation and / or after

-13 activates 2 by launching the vehicle moving in the test area. The activated components 2 develop a visible aerosol cloud, which spreads in the test area similar to the smoke from a real fire when burning gasoline, diesel and others. Throughout the test, that is to say, at least for the duration of movement of the aerosol cloud within the test area, the edge area of the cloud is monitored. This tracking can be provided by a moving video device, such as a video camera 15 mounted on a separate vehicle, through which video recording is continuously made to visualize the test progress.

The above method according to the invention and the function for this method of the proposed device according to the invention are shown in figures 8 and 9 in the case of a statically placed generator, of which FIG. 8 demonstrates the development and propagation of an aerosol cloud in a room vented by a duct system and FIG. 9 in a room with only natural ventilation using a skylight. In these pictures is marked with a line called. a safe line h, which is a height limit showing how far away from the floor of the room it is still safe for people to breathe in the fire area in case of use, resp. operation, means of fire ventilation present. The arrows indicate the natural air supply through the construction openings.

Fig. 10 shows the performance of a fire ventilation test in a tunnel using a generator mounted on a support structure 14 mounted on a vehicle during a standing test. In the case of A, the vehicle with the generator is located in the central part of the tunnel under test, in case of B it is in the region of the tunnel beginning, in case of C it is in the region of the tunnel end. In all cases A, B, C, two auxiliary vehicles are used for tracking, each with a video camera 15 that stands near the edge of the aerosol cloud and slides back and forth as the aerosol cloud initially propagates and eventually decreases by venting. The technical solution allows these vehicles and camcorder 15 to be operated by persons without danger to life and health. All vehicles in the tunnel area are without any risk of fire.

Fig. 11 shows the performance of a fire ventilation test in a tunnel by means of generators mounted on a supporting structure 14, mounted on vehicles during the mobile test. In case of A, two generators are activated in the central part of the tunnel under test, then the vehicles leave the aerosol spread towards the end of the tunnel. In case of B, two generators are activated already in the start area of the test

-14 tunnel, then the vehicles leave the aerosol spread towards the end of the tunnel. In case of C, the two generators are activated only at the end of the tunnel being tested, then the vehicles leave the aerosol spread towards the beginning of the tunnel. In all cases A, B, C, one or two auxiliary vehicles with a video camera 15 can be used to watch and make a video, as in the case described in FIG. 10th

The above-mentioned variants of the solution according to the technical solution demonstrate and never limit. Thus, various other combinations of device design and method are possible under the conditions of the invention.

Claims (13)

Method for testing the functionality of fire ventilation, characterized in that a non-toxic aerosol generator simulating combustion gases having a predetermined number of components (2) is placed in the test area, these components (2) are activated, and then the propagation of the generated aerosol is monitored making a video recording and measuring the values necessary to evaluate the functionality of the fire ventilation in a given area, measuring at least the air flow rate, the temperature in the area of the aerosol generator, the temperature in the area outside the generator and time, and finally smoke, for example arising from the combustion of petrol and diesel, measured in the test area and based on the results obtained, the functionality of the fire ventilation of the test area shall be evaluated. Method for testing the functionality of fire ventilation according to claim 1, characterized in that the generator develops a non-toxic aerosol at a temperature of 600 to 1300 ° C consisting of a mixture of solid and gaseous phases, of which the solid phase consists of particles of 1 to 5 µm m based on potassium carbonate, potassium bicarbonate and carbon, and the gas phase is a medium based on carbon dioxide, water vapor, nitrous gases, nitrogen and ammonia. Method for verifying the functionality of a fire ventilation system according to claims 1 and 2, characterized in that the non-toxic aerosol is generated in an amount of 3 to 100 m ³ / s, the specific amount to be generated for a particular verification test being predetermined within said range. the design parameters of the fire ventilation for the test area, for example at the maximum permitted by the project. Method for verifying the functionality of fire ventilation according to claims 1 to 3, characterized in that during the test the air flow rate including the aerosol contained, the temperature in the area of the aerosol generator and in the test area, the optical density of the aerosol are monitored. The exchange time of gases and polluted air is measured as a function of the volume exchange of air masses and the optical density of the aerosol. -165. Method for verifying the functionality of fire ventilation according to claims 1 to 4, characterized in that the optical density of the aerosol at different height levels is detected in the test area during the test by video recording and / or measurement at different heights. Method for verifying the functionality of a fire ventilation system according to claims 1 to 5, characterized in that air conditioning devices of the test area are in operation during the aerosol generation and aerosol tracing monitoring in the test area. Method for verifying the functionality of a fire ventilation system according to claims 1 to 6, characterized in that at least one non-toxic aerosol generator is placed in such a position and thus accessible to the vehicle before the activation of the contained component (2). to allow the aerosol to spread freely into the surrounding area, the vehicle and the compound (2) being transported to the compound activation site (2) and then, during activation and / or after activation of the compound (2), the vehicle moves within In the course of the test, a moving video device, such as a video camera 15, is placed on another vehicle for continuous video recording, and a continuous video recording is made throughout the test area. allowing visualization of the test progress. Apparatus for carrying out a method for verifying the functionality of a fire ventilation system according to any one of claims 1 to 7, comprising a generator comprising containers (1) of a non-combustible solid material, for example steel, having an internal cavity which are at least partially filled with a combustible component (2). in that the composition (2) of the containers (1) forms a source of a non-toxic aerosol imitating combustion products, namely an aerosol consisting of 1 to 5 µm solid particles and non-toxic gaseous materials, wherein in addition to the composition (2) is contained in the container (1) only the firing device (3) is contained and above the composition (2) with the firing device (3) there is only free space in the vessels (1), and these vessels (1) are in the number of 4 to 10 pieces stored in at least one storage non-combustible solid material, such as steel, and here provided with a common perforated lid ( 9). -179. Apparatus for carrying out a method for testing the functionality of a fire ventilation system according to claim 8, characterized in that the receptacle for containers (1) is in the form of a stand, the upper part of which forms a receptacle (5) for receptacles (1). (6) with at least one internal cavity for the necessary electrical elements, a firing device (3), for example for conductors (4). Apparatus for carrying out a method for testing the functionality of a fire ventilation system according to claim 9, characterized in that the bed (5) is provided with at least one opening (7) and the inner cavity of the pedestal (6) is passable adjoining said opening (7). the base (6) is provided with at least one element stabilizing its position relative to the support, for example a support plate (8) formed below. Apparatus for carrying out a method for verifying the functionality of a fire ventilation system according to claims 9 and 10, characterized in that the rack is at least one stored in a tub / (11) of a non-combustible solid material, for example steel, said tub (11) comprising at least the bottom (12) and the full-peripheral rim (13), the stand being fixed, immovably fixed to the bottom (12) of the tub (11). Apparatus for carrying out a method for testing the functionality of a fire ventilation system according to claim 11, characterized in that the tub (11) comprises one to twenty racks, wherein at least some of the racks contained have a bed (5) fully filled with containers (1) covered with a perforated lid ( 9). Apparatus for carrying out a method for verifying the functionality of a fire ventilation system according to claim 12, characterized in that the trough (11) is supported on a supporting structure (14) of a movable means, for example a vehicle, at least in the region of the lid (9) freely from the surrounding space . Apparatus for carrying out a method for verifying the functionality of a fire ventilation system according to any one of claims 8 to 13, characterized in that component (2) is a non-toxic aerosol generating material when fired, the solid particles of which contain a mixture of potassium carbonate, potassium bicarbonate, carbon. the gas phase of which comprises a mixture of carbon dioxide, water vapor, nitrous gases, nitrogen and ammonia.