RU2668639C2 - Method of evaluation of fire particles of metals and device for its implementation - Google Patents

Abstract

FIELD: fire-fighting equipment.SUBSTANCE: invention relates to experimental research of fire safety of electrical installations, in particular to estimation of flammability of metal particles, formed during short circuits (KZ) of veins of electric wires and cables in emergency operation of electric networks. A method for estimating fire hazard of metal particles formed during short circuit and device for its implementation (variants) in which ignition of particles are produced in zone of short-circuit arc discharge with parameter equivalent to process under study, particles are dumped onto reference combustible material and in frequency ignitions determine probability of fire of material. In device in zone of short-circuit formation, conductive contact surface is made in form of two electrodes from conductors under investigation, which are fixed in insulated holders in such a way that, when in contact, they can intersect in mutually perpendicular planes and in case of short-circuiting they form fire-hazardous particles of investigated metal. Device has camera, at bottom of which there is set of cells with combustible material being studied.EFFECT: technical result is increase in reliability and accuracy of research.3 cl, 2 dwg

Description

The invention relates to the field of experimental study of the fire safety of electrical installations, in particular, to the assessment of the flammability of metal particles formed during short circuits (CI) of electrical conductors and cables in emergency operation of electrical networks.

Emergency modes of electrical installations, as well as their improper operation, annually account for more than 25% of all fires recorded in the country. In almost every major fire of one of the main versions of the cause of the fire, a “short circuit in the wiring” is put forward. The sources of ignition of combustible materials during a short circuit are both the arc discharge itself and burning metal particles flying from the KZ zone. Particles of metal, being carriers of high thermal energy, represent potential sources of fire, especially when it comes into contact with combustible materials (combustible dust, fabrics, plastics, wood, etc.).

A known method and device for studying the burning effect of an electric arc during a short circuit in fire hazardous environments (G.I.Smelkov. Fire hazard of electrical wiring under emergency conditions. - M.: Energoatomizdat, 1984, p. 52-53), containing a power transformer, a conductor, one of the ends of which is connected through a measurement unit, and a contactor to a power transformer, conducting a contact surface connected through a limiting resistance to a power transformer, an artificial short-circuit formation zone circuit in contact with the conductor.

The conductive contact surface is formed by the lateral surface of the steel pipe 0.5 m long. The conductor 1 m long is placed inside the pipe and has a bare section 5-6 mm long in contact with the zone of formation of artificial short circuit, made in the form of a section of the inner surface of the steel pipe. A loop oscilloscope was used as a measurement unit. A voltage of 220 V is applied between the conductor and the steel pipe. At the point of contact of the conductor and the portion of the inner surface of the side wall of the steel pipe, either an artificial short circuit through an electric arc or an artificial non-arc metal short circuit occurs.

As a result, the conductor is burned, or the exposed section of the conductor is welded to the portion of the inner surface of the side wall of the steel pipe. During the study, the instantaneous values of current and voltage are recorded by a loop oscilloscope, according to which the burning effect of the electric arc during a short circuit and the burning time are judged. The limit time for burning a conductor corresponds to the steady burning of an electric arc.

A device is known for studying the burning effect of an electric arc during a short circuit (RF Patent No. 2249826, IPC G01R 31/2, published April 10, 2005), which contains a power transformer, a conductor connected through a measuring unit and a contactor to a power transformer that conducts a contact surface connected through a limiting resistance to a power transformer, as well as an artificial short circuit zone in contact with the conductor. In this device, the zone of formation of artificial short circuit is made in the form of a uniform layer of powder graphite deposited on a conductive contact surface.

The disadvantages of the above method and device for studying the burning effect of an electric arc is the limitation of their use to answer the question about the incendiary ability of metal particles formed in the short circuit zone.

A known method for determining the involvement of metal particles during short circuits in electrical wiring to the occurrence of fires (GI Smelkov and others. Methods for determining the involvement of emergency conditions in fires in electrical devices. M: Stroyizdat, 1980, 58 S.). A sample of solid combustible material is taken from the fire site and a group of its combustibility is established, depending on which, according to the tabular data, the probability of material ignition is determined. However, the accuracy of the results obtained is very unsatisfactory due to the huge amount of combustible substances that do not have the necessary tabular values.

Closest to the proposed invention by its technical nature and the achieved result is a method for determining the fire hazard of metal particles (Copyright certificate SU No. 834484, Bull. No. 20, 1981), adopted as a prototype of the claimed technical solution.

The metal particle under investigation is weighed in a high-frequency electromagnetic field, ignited, for example, from the arc of a plasma torch, blown through with an air flow at a rate that varies according to the law of particle incidence in the air, and its thermal energy is determined, for example, by the calorimetric method. The thermal energy obtained and the particle surface area determine its energy density. Comparing the obtained value of the particle energy density with the ignition energy density of the combustible material taken from the reference data, one can judge the fire hazard of a particle of a certain metal relative to a given combustible material and for a specific drop height.

The disadvantage of the described method is the low accuracy and reliability of the research results due to the large number of assumptions in the calculations, as well as the high cost and complexity of the equipment used (high-frequency high-power installation, plasmatron, precision microcalorimeter, wind tunnel with adjustable air flow and various measuring instruments and equipment).

The objective of the present invention is to increase the reliability and accuracy of ongoing research, as well as expanding the scope of the data obtained, for example, conducting expert assessments in fire cases.

The essence of the proposed method lies in the fact that in the method for assessing the fire hazard of metal particles, the particles of the test material of the conductors of the conductors are ignited and, to determine their fire hazard, are discharged onto combustible material, the particles being ignited in the short circuit arc discharge zone, with parameters equivalent to the process under study, and the particles are discharged onto a reference combustible material and the probability of material ignition is determined by the ignition frequency.

The essence of the claimed device lies in the fact that in the device for assessing the fire hazard of metal particles containing a power transformer, conductors connected through a measuring unit and limiting the resistance to the power transformer, an artificial short circuit zone, while in the short circuit zone, conductive contact the surface is made in the form of two electrodes from the studied conductors, which are fixed in insulated holders so that when in contact they had the opportunity to intersect in mutually perpendicular planes and, during a short circuit, formed fire-hazardous particles of the metal under study, and at the bottom of the chamber a set of cells with the combustible material under study was located.

The technical effect realized by the claimed method for determining the fire hazard of metal particles is determined by the following.

Ignition of particles is carried out directly in the zone of an arc discharge of a short circuit with parameters equivalent to the process under study, which ensures high reproducibility of the physicotechnical characteristics of the resulting fire hazardous metal particles (their number, size, heat capacity, departure speed, etc.). This significantly increases the reliability and accuracy of the research.

The technical effect realized by the claimed device is determined by the following.

In the zone of formation of a short circuit, the conductive contact surface is made in the form of two electrodes of the studied conductors, which can be remotely approached, which are fixed in insulated holders so that when they touch, they intersect in mutually perpendicular planes and, when shorted, form fire hazardous particles of the metal under study.

This solution, based on the same parameters of the speed of approach of the electrodes and the force of their mutual pressing when in contact, ensures the uniqueness and comparability of the experiments, and also increases the safety of research.

The technical effect realized by the claimed device (according to a variant of the device according to paragraph 3 of the claims) is determined by the following.

The device has a camera, at the bottom of which is a partitioned set of cells with the studied combustible material. Ignition (or non-ignition) of the material occurs in the cells when burning or molten particles enter.

Thus, the ignition frequency determines the probability of material ignition. The obtained results are the necessary initial data for calculating the probability of a fire at the facility.

Analysis of other technical solutions showed that the known methods and devices do not solve the previously mentioned problems, solved by the claimed method (options) and device (options).

Based on the foregoing, we can conclude that the claimed technical solution meets the criterion of "inventive step", and the invention itself is new.

In FIG. 1 shows a diagram of a device that implements the inventive method, FIG. 2 - electrical diagram of the device.

A device for assessing the fire hazard of metal particles formed during a short circuit includes a chamber 1 with a volume of 0.36 m ³ , a contactor 2 and a tray with cells for combustible material 3.

Chamber 1 is a steel structure 600 × 600 × 1000 mm in size, which is installed in the test room in a vertical position. In order to prevent scattering to the sides of the formed particles from three sides, the chamber has metal walls. In the upper part of the chamber, a contactor 2 is installed, and in the lower part there is a pallet 3 with cells 6 filled with combustible material.

The switch is made on the basis of a controlled asynchronous single-phase reversible motor 4, for example, RD-09 P2A, with a rotation speed of 30 rpm.

To convert rotational motion into translational gearbox 5 is used using a worm gear. The samples are fastened in insulated holders, one of which is stationary, and the movement of the other is controlled from the remote control, which provides the supply and removal of live conductors with a linear speed of 140 mm / min. The movement of the movable electrode 6 is carried out remotely and at the extreme points of the mechanism is limited by limit switches.

The circuit of the contactor 2 is assembled on a fiberglass plate with a thickness of 10 mm, with dimensions of 800 × 600 mm. A rectangular hole of 80 × 120 mm is cut in the center of the board, through which electrodes are fixed. The board with the contactor mounted on it is installed in the upper part of the camera.

The electrodes are made from test samples of wire strands. The length of each of the electrodes is 150 mm. The end of one of the electrodes at a length of 40 mm is bent at an angle of 90 degrees. The electrodes are inserted into insulated holders so that when they touch, they intersect in mutually perpendicular planes.

The pallet with cells for combustible material is a steel pan 600 × 600 mm, in which 16 cells 7 of 150 × 150 mm in size with a side height of 60 mm made of non-combustible material are closely mounted. Surgical cotton or other test material 8 is placed in the cells in a uniform thin layer.

In FIG. 2 is a diagram of external connections designed to power and protect the installation. Any power transformer 9 with a capacity of at least 320 kVA and a secondary voltage of 220/380 V (for example, ТМ / 6 / 0.4) can be used as a power source. The selectivity of protection is provided by two circuit breakers 10, for example, VA88-33 160A and BA49-29 63A. The ratio of the protection devices is selected in such a way that with each short circuit of the conductors the 63A device is triggered and the VA88-33 device (at 160A) remains in the on position.

Regulation of short-circuit current is carried out using additional resistance 11, connected in series to the network with moving 13 and fixed 14 electrodes located in the zone of short circuit formation, and is controlled by measuring unit 12.

As a combustible material, either a reference flammable material (for example, medical cotton wool according to GOST 5556-81), or a sample or its analogue studied during criminalistic tests can be used.

Thus, during the formation of hot or burning particles due to a short circuit of the conductors and the ingress of particles into cells with combustible material, ignition (or non-ignition) of surgical cotton wool occurs in individual cells.

The ignition frequency of combustible material Qin is determined by the formula for multiplying the probabilities of two dependent events:

Qв = Pn × Рв = m / n, where:

Pn = n ₁ / n is the probability of occurrence of fire hazardous metal particles in short-circuit experiments with phase-zero loop resistance;

Pb = m / n ₁ - the probability of ignition of a combustible material in experiments in which the appearance of particles was observed;

n ₁ is the total number of cells in pallets in a series of n-experiments;

n is the number of experiments;

m is the total number of sunburns in the cells of the pallet in a series of n-experiments.

Based on a comparison of indicators on ignition frequencies, a conclusion is drawn about the fire hazard of metal particles generated as a result of a short circuit of aluminum or copper cores of wires relative to the studied combustible material.

Claims (3)

1. The method of assessing the fire hazard of metal particles, which consists in the fact that the particles of the studied material of the conductors of the conductors are ignited and, to determine their fire hazard, are discharged onto combustible material, characterized in that the ignition of the particles is carried out in the zone of an arc discharge of a short circuit with parameters equivalent to the process, the particles are discharged onto a reference combustible material and the probability of material ignition is determined by the ignition frequency. 2. A device for assessing the fire hazard of metal particles, containing a power transformer, conductors connected through a measuring unit and limiting the resistance to the power transformer, an artificial short circuit zone, characterized in that in the short circuit zone the conductive contact surface is made in the form of two electrodes from the studied conductors, which are fixed in insulated holders in such a way that, upon contact, they have the opportunity to intersect the set perpendicular planes and the short-circuit formed of the metal particles flammable. 3. The device according to p. 2, characterized in that it has a camera at the bottom of which is a set of cells with the studied combustible material.

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