EA007641B1 - Method for detecting emergency and/or pre-emergency situations - Google Patents

Abstract

The invention relates to the field of technological control, to methods of early detection of emergency situations associated with off-optimum operational situations of technological equipment.The invention aim is to increase sensitivity of measurements by detecting at early stage emergency/pre-emergency situations.The method is based on regular measurements of environmental parameters in controllable premises and processing the obtained data, wherein countable concentration of aerosol particles in air in controllable premises is used as environmental parameter.

Description

The invention relates to the field of monitoring the operation of technological or other equipment, more specifically, to methods of early detection of emergency situations and diagnostics of pre-emergency conditions associated with abnormal operation of technological equipment.

In order to reduce damage from an accident, control is tried to be organized in such a way as to detect an emergency at the earliest possible stage, up to registering such deviations from the normal course of the technological process that have not yet managed to stop or break down the process equipment (pre-emergency situation). ). In case of detection of a pre-emergency situation, it is possible not only to reduce the damage, but also to prevent the development of an accident.

Currently, systems are used to detect emergencies, which are based on recording the effects of an accident. Typically, such a system includes a sensor that detects a deviation from the normal course of the process (no pressure, a decrease or increase in temperature, a power outage or a deviation in the electrical circuit parameters, a drop in the liquid level, etc.). Systems of this type include fire protection systems.

The existing fire prevention systems for detecting emergency situations (see Korolchenko A. Ya. Fire and explosion hazard of industrial dust. M., Chemistry, 1986, p. 189) are based on the registration of significant changes in the mass concentration of aerosols generated in the room (smoke) or temperature changes. In fact, they also only record the consequences of a critical situation that has already arisen - a fire. Thus, sensors that react to a rise in temperature work only after the air in the immediate vicinity of the sensor is heated (due to natural air convection or ventilation air flow). This process, as a rule, takes too much time, and the response to a fire is late.

In fire systems of another type that use mass concentration sensors (airbags 76-98. Fire detectors. General technical requirements. Test methods), the system requires to exceed (usually by an order of magnitude) sanitary standards for the content of airborne particles (standards for different chemical composition ranges from 1-75 mg / m ³ ), which corresponds to a countable concentration of particles in the range of 10 ⁹ -10 ¹² h / m ³ . Considering that in ordinary atmospheric air the content of the dispersed phase suspended in air is 0.1-0.5 mg / m ³ (i.e. the countable concentration of particles is 10 ⁸ -10 ⁹ h / m ³ ), it is easy to conclude that for the operation of the system, it is necessary to increase the calculated concentration of particles in the air by two to four orders of magnitude.

Thus, the response time of such a system to fire is very significant. In fact, it only registers the consequences of an already arising fire. Naturally, the reaction to a fire (that is, the necessary operational actions) can be very late.

The technical task of the present invention is to increase the sensitivity of measurements and, thus, to ensure the detection of an emergency or pre-emergency situation at an earlier stage, as well as raising the informativeness of measurements to a level that ensures the determination of the type of process that caused the emergency or pre-emergency situation.

The technical result is achieved by the fact that in the method of detecting an emergency or pre-emergency situation associated with abnormal operation of a process or other equipment installed in a controlled room, the value of the environmental parameter in the controlled room is periodically measured, the measured value of the controlled environmental parameter is measured with the value measured under normal operating conditions of technological or other equipment, and by changing the controlled parameter of the environment the presence of an emergency or pre-emergency situation is judged, while counting concentration of aerosols in the air of the controlled room is used as a controlled parameter of the environment, and if changes in the controlled parameter of the environment are detected, the size distribution function of the particles of aerosols in the air of the controlled room is additionally measured; the measured particle size distribution function of aerosols with a set of aerosol particle size distribution functions, I single out in various emergency or pre-emergency situations, and judge the process that caused the emergency or pre-emergency situation.

The basis of the described method of detecting emergency and (or) emergency situations associated with abnormal operation of the process or other equipment installed in a controlled room, is a fundamentally new approach. He uses the principle of registration of individual particles of aerosols in a wide range of sizes, which allows to determine the counting concentration and the dispersed composition of the aerosol component of the air in a controlled room.

Due to the fact that the counting concentration of aerosol particles in the air is used as a controlled parameter of the environment, an increase in the sensitivity of measurements is achieved. Indeed, when measuring the number concentration of aerosols (usually carried out using photoelectric devices — laser counters and spectrometers of aerosol particles), the number of individual particles of a certain size per unit of air volume is measured, while in traditional sensors the mass is determined (by optical, radiometric or other methods) aerosol concentration, i.e. the mass of all aerosol particles in a unit of air volume. To trigger mass concentration sensors, it is necessary to have at least

- 1,007,641 how many cells or thousands (depending on size) of aerosol particles, while a single particle is enough to trigger a laser aerosol counter. Thus, the measurement sensitivity when using as a controllable parameter a counting concentration of aerosol particles is at least 2-3 orders of magnitude higher than when measuring the mass concentration of particles (see W. White. Clean room technology. M., Klinrum, 2002 , pp. 150-151). This is confirmed by numerous experimental data (Ls \\ 'ogt 1)

Another important advantage of the principle of measuring individual particles of aerosols is the unique ability to detect emergencies of various nature. This possibility is due to the fact that almost any significant change in the operating mode of installations or equipment, mechanical damage, process disturbance and other emergencies are accompanied by quite sharp fluctuations (usually in the direction of amplification) of aerosol generation processes, and the registration of these changes occurs on very early stage, often before the appearance of any visual signs of the process, which makes it possible not only to record the fact of an emergency tion, but also to prevent it, which is fundamentally impossible in the analogs.

Moreover, since the control devices for aerosol micropollution simultaneously measure not only the counting concentration, but also the dispersed composition of particles, in many cases it is possible to compare the characteristic changes in the distribution function of aerosol particles with a particular process (aerosol label). Thus, it is possible not only to fix the occurrence of an emergency, but also to draw some preliminary conclusions about its nature (fire, sparking of contacts, increased friction in bearings, etc.).

The ability to compare the dispersed composition of aerosols with one or another violation of the technological process was proved by the authors experimentally. FIG. Figures 1 and 2 show the dispersed composition experimentally measured by the authors and the countable concentration of aerosol particles formed during various specific deviations from the normal operation of the equipment. Firstly, one can clearly see an increase in the number concentration of particles in time (that is, as simulated emergencies develop) and, secondly, the characteristic (and different from each other) “aerosol labels” of each of the processes.

The method of detecting emergency and (or) emergency situations was implemented by the authors and on the scale of real industrial premises with working technological equipment.

Example 1 of the method.

Registration of pre-emergency operation of a power transformer.

The prospect of using aerosol monitoring to control electrical equipment was confirmed by experimental measurements. In the experiments it was shown that various deviations from the normal course of the technological process (heating and destruction of electrical insulation, sparking electrical contacts, heating paints, varnishes and sealants, mechanical friction and accompanying heating, etc.) lead to the generation of submicron aerosols with characteristic particle size spectra . At the same time, particle generation often advances the appearance of odor or other visible manifestations of processes.

In addition, a special experiment was conducted that modeled the regular and pre-emergency modes of operation of electrical equipment (power transformer) located in the production area. The results are presented in FIG. 3

Experimental data allow us to state with confidence that changes in the counting concentration of aerosols in a closed air volume, accompanying work in a pre-emergency mode, make it possible not only to fix the fact of an emergency, but also to prevent it.

Example 2 of the method.

Early detection of leaks and defects in steam lines.

The high effectiveness of monitoring aerosols to detect leaks and defects in steam lines was confirmed in the course of experimental studies of the dispersed composition and counting concentration of aerosol particles in a room with simulated steam leakage.

The experiments were carried out directly in the technological room with an area of 60 m ² , equipped with a system of ventilation and air purification. Several units of technological equipment were installed in the room, therefore both the distribution conditions of the air flow and the cleanliness of the air in the room can be considered to be in good agreement with the actual conditions of the technological rooms. Measured number concentration and dispersion of particles in the room. The results of measurements of total total concentration are presented in FIG. four.

According to the results of a series of experiments (on or off ventilation, measurements near the steam generator, at the maximum possible distance, while monitoring the total air flow from the room), it can be noted that even under conditions of significant dilution of the generated particles in the air volume of the room, it was possible very quickly (after 4 min after the start of steam generation) clearly record a significant (5-7 times) increase in the concentration of aerosol particles, in particular

- 2 007641 submicron particle sizes. At the same time, a humidity sensor installed in the same room recorded only minor fluctuations in the relative humidity (see graph in Fig. 4).

Thus, using the methods of aerosol monitoring of indoor air, we managed to confidently detect the leakage of steam in the room at the stage when the humidity sensors had not yet had time to record the change in the value of air humidity. Moreover, this effect was also reproduced when monitoring the total air flow from the room, i.e. with significant dilution.

The method of early detection of emergency and (or) pre-emergency conditions may be of interest for objects with a high accident price, such as power facilities (including nuclear power plants), control centers and systems, launch complexes of rockets, space stations, radio and television broadcasting systems, collection centers information and management of gas and oil pipelines and electrical networks, plants for processing nuclear fuel, etc.

Claims (1)

A method for detecting an emergency or pre-emergency situation associated with an abnormal mode of operation of technological or other equipment installed in a controlled room, which consists in periodically measuring the value of the environmental parameter in the controlled room, comparing the measured value of the controlled environmental parameter with the value measured with standard the operating mode of technological or other equipment, and the change in the controlled environmental parameter is judged on the presence of avar pre-emergency situation, characterized in that as a controlled environmental parameter, a counted concentration of aerosol particles in the air of the controlled room is used, and when changes in the controlled environmental parameter are detected, the distribution function of the size of aerosol particles in the air of the controlled room is additionally measured, the form of the measured distribution function is compared by the size of aerosol particles with a set of distribution functions by the size of aerosol particles released in various emergency or pre-emergency situations, and judge the process that caused the emergency or pre-emergency situation.