RU2662012C1 - Device for the determination of extinguishing concentration when supplying fine-dispersed compositions in the rising stream - Google Patents

Abstract

FIELD: laboratory equipment.

SUBSTANCE: invention relates to laboratory equipment, in particular to devices used to determine the physico-chemical properties of fine-dispersed fire-extinguishing compositions. In an apparatus for determining the fire extinguishing concentration when fine particles are fed into an ascending jet consisting of a compressor, a receiver, a rotameter, a glass casing, a burner, a vessel for adjusting the level of fuel in the burner, the supply of the composition of the composition in the ascending jet is made with the help of an electromagnetic pneumatic distributor, and the time for lifting the composition is determined by frame-by-frame video recording using a high-speed video camera.

EFFECT: invention provides reliability and repeatability of experimental results by definition of the minimum fire-extinguishing concentration of fine-dispersed composition in the volume to increase the quenching efficiency when using fire-extinguishing fine dispersions.

1 cl, 2 dwg

Description

The claimed technical solution relates to the field of creating laboratory equipment and instruments used to determine the physicochemical properties of finely dispersed extinguishing compositions.

A number of installations are known: (Schreiber G., Porst P. Fire extinguishing agents. Chemical and physical processes during combustion and extinguishing. - M .: Stroyizdat, 1975 -240 p.) To determine the fire extinguishing efficiency of finely dispersed compositions. The determination was made in the laboratory or in practical conditions.

1. Install Dufress. In a vertically mounted cylinder with a height of 20 cm, diameter 6 cm, along the axis of which there is a tube with a burning light gas supplied at a speed of 0.5 l / min, a certain amount of extinguishing powder is pumped from the bottom up with an air stream. Fire extinguishing effectiveness is determined by the minimum amount of powder sufficient for one extinguishing. The disadvantage of this method is that the mass of a sample of powder is determined, and not the minimum extinguishing concentration in the volume.

2. Installation of Lee and Robertson. The mobile vessel is equipped with two crucibles with a diameter of about 2.5 cm, which move slowly under the scattering device. One crucible is used to measure the mass of the powder used to extinguish, the other contains fuel - burning heptane. The quenching process is monitored using a photocell. The disadvantage of this method is that the mass of a sample of powder is determined, and not the minimum extinguishing concentration in the volume.

3. Installation of Dessart and Malarm. In the experiments, the following test conditions were observed:

- the air flow in the glass tube (3.33 l / min at 25 ° C and 760 mm Hg) was regulated and controlled by a device consisting of a tap and a regulator with a water pressure gauge;

- the flow of combustible gas (0.9 l / min industrial butane) was regulated and controlled by a tap and a rotameter;

- the powder was supplied using nitrogen supplied from a steel cylinder under a pressure of 760 mm Hg. in the amount of 1.2 liters of gas per experiment.

After creating the specified conditions in the installation, a certain amount of extinguishing powder (with an accuracy of 0.1 g) was introduced into the curved tube of the injector, which was supplied to the gas flame through the hole of the magnetic valve, which opened the passage to the working gas. The experiment was repeated seven times with the same amount of powder.

The minimum amount of powder that can be used to extinguish six extinguishes from seven experiments determines the conditional extinguishing efficiency of the powder. It is expressed by the number of theoretically possible quenching of 10 g of powder. The disadvantage of this method is the difficulty of observing the constant conditions of the experiments.

A known installation for determining the extinguishing concentration of extinguishing powders, previously used in Russia (Atamanenko M.E., Taysumov H.A., Pikhienko V.V. Laboratory apparatus for determining the extinguishing efficiency of powders. - Sat: “Fire extinguishing means and methods.” M ., VNIIPO, 1981, pp. 15-20.), Which is selected as a prototype. The tests were carried out in a laboratory setup made of glass with a burner with a diameter of 10 mm. The powder was fed into the flame by a stream of air, which simultaneously went to the oxidation of the fuel. The sequence of operations is as follows. A three-way valve was installed in a position where the air flow from the nozzle moves up. A sample of a powder composition was introduced through the window. Using a vessel connected to the burner with a flexible hose, the required fuel level was regulated. The casing was removed from the thin section and the liquid was ignited. Returning the casing to its original place, set the required air flow rate. The flame height was determined on a scale and after that the three-way valve was turned 180 °. Thus, a stream of air going to the oxidation of fuel was directed to a sample of powder, which was carried away into the tubes, and then into the casing. The minimum hitch at which quenching was achieved was selected. Extinguishing time was not more than 1 s. In order to recalculate the weight of the powder sample to the volume quenching concentration, it was assumed that the entire portion of the powder is evenly distributed over the volume of the casing located above the upper edge of the burner and having a height of 10 cm

The disadvantage of this technique is the high instability in the repeatability of test results. This is mainly due to two circumstances: the fact that the volume of the flame, in which the quenching was achieved, was taken as the volume of the entire casing, although the flame occupied only part of it; and also the fact that the rotation of the three-way valve, providing the supply of extinguishing powder, is carried out manually, which also causes an increase in the spread in the results.

The aim of the invention is to ensure the reliability and repeatability of the results of experiments to determine the minimum extinguishing concentration of finely dispersed composition in a volume to increase the extinguishing efficiency when using extinguishing finely dispersed compositions.

The essence of the claimed device lies in the fact that the device for determining the extinguishing concentration when feeding finely dispersed compositions into an upward jet, consisting of a compressor, receiver, rotameter, glass casing, burner, vessel for adjusting the level of fuel in the burner, additionally contains an electromagnetic pneumatic distributor and a high-speed video camera to determine the time of lifting the composition, excluding the influence of the operator on the experience by observing the constancy of the response time of the device.

The technical effect of the claimed device is that the use of an electromagnetic pneumatic distributor eliminates the influence of the operator on the experience, since its response time is constant (no more than 0.1 s). Single-frame video recording allows determining the rise time of finely dispersed composition with an accuracy of at least 0.04 s (25 frames per second) and 0.002 s (500 frames per second) and significantly increasing the accuracy (repeatability) of experiments.

In FIG. 1 shows a device for determining extinguishing concentration when feeding finely dispersed compositions in an upward stream. In FIG. 2 shows a calibration chart for the rotameter.

A device for determining the extinguishing concentration when feeding finely dispersed compositions into the upward stream consists of: compressor 1, receiver 2, hose 3, tee 4, valve 5, rotameter 6, electromagnetic air distributor 7, feeder 8, glass casing 9, burner 10, nozzle 11, fuel 12, a vessel for adjusting the level of fuel in the burner 13, hitch composition 14, video camera 15.

The device operates as follows:

To determine the extinguishing concentration, the input parameters are set:

G - air flow, m ³ / s;

m is the mass of the sample, kg.

Air flow was set in advance with a rotameter calibrated in advance.

The weight of the sample m was placed in a laboratory installation at a regular place 14, the compressor 1 was turned on, the required air flow rate was set at rotameter 6, which corresponded to 15 l / min, the combustible liquid was burned in the burner 10, then the glass casing 9 was put on, recording was started on the camera 15 and they actuated the electromagnetic pneumatic distributor 7. If the focus was not extinguished, then took a large sample of mass m ₁ . In the case of extinguishing the source by a m ₁ sample, the mass of the desired sample was determined by the method of successive approximations:

where m is the mass of the smaller sample, kg;

m ₁ is the mass of the larger sample, kg.

where m _and - the desired mass of the sample, kg.

In case of unsuccessful extinguishing, the weight of the sample was successively increased:

Thus, the mass of the finely dispersed composition closest to the minimum extinguishing concentration was found in three successive successful experiments.

The rise time of the composition τ _{p was} determined using a frame-by-frame video recording of the experiment. The volume of the air-dispersed mixture in the feeder V _{p was} calculated by the dependence:

where G is the air flow, m ³ / s;

τ _p - the time of lifting the composition in the feeder, C.

Next, the extinguishing concentration C _o

The use of an electromagnetic pneumatic distributor eliminates the operator’s influence on the experience, since its response time was constant (no more than 0.1 s). Frame-by-frame video recording allows determining the time τ _r with an accuracy of at least 0.04 s (25 frames per second) and 0.002 s (500 frames per second) and significantly increasing the accuracy (repeatability) of experiments.

Claims (1)

A device for determining the extinguishing concentration when feeding finely dispersed compositions into the upward stream, consisting of a compressor, receiver, rotameter, glass casing, burner, vessel for adjusting the fuel level in the burner, characterized in that it additionally contains an electromagnetic pneumatic distributor and a high-speed video camera for determining the rise time composition, eliminating the influence of the operator on the experience by observing the constancy of the response time of the device.

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