RU2160149C1 - Toxic air decontaminating device - Google Patents

Abstract

FIELD: adsorption engineering; decontaminating atmosphere in civil-defense protective works. SUBSTANCE: device has two absorbing filters installed in parallel with overshoot warning unit connected to delivery air conduit and fan at outlet. It also has set of four sealed valves one installed at inlet and other at outlet of each absorbing filter. Detector and ejector are mounted in tandem on delivery air conduit upstream of sealed valves; low-pressure chamber of ejector communicates with suction line of fan by means of newly introduced bypass air conduit through additional series-connected heat exchanger and safety chamber incorporating heating element and provided in addition with inlet and outlet sealed valves. Outlet of each absorbing filter directly communicates with inlet of other absorbing filter via additional sections of air conduits incorporating sealed valves. In addition, ejector inlet at delivery air conduit communicates through sealed valve with inlet of injector low-pressure chamber; valve intended to pass air from protective works is installed directly at outlet of safety chamber. EFFECT: improved economic efficiency due to saving adsorbent. 1 dwg

Description

 The invention relates to the field of adsorption technology and can be used for air purification of protective structures of civil defense from toxic substances during the filtering period.

 A known design of adsorption apparatuses of periodic action with a fixed adsorbent layer enclosed between perforated devices for gas inlet and outlet (USSR Author's Certificate N 803954 according to B 01 D 53/26 for 1978; Keltsev NM Basics of adsorption technology. - M. : "Chemistry", 1976, p. 253).

 The disadvantage of these devices is that during the sorption, the sorbate zone is smeared along the charge layer; as a result, when the maximum permissible concentration of sorbitol appears at the outlet of the adsorption apparatus, it needs to be stopped, followed by replacement with a new one or regeneration of the sorbent, while not fully worked out. This entails a decrease in the efficiency of use of the adsorbent.

 The closest in technical essence to the present invention is a device comprising two parallel filter slots of the filter-absorber connected to a supply duct and a fan at the outlet, as well as a system of four pressure valves installed one at the inlet and outlet of each of the filter-absorbers (Kammer Yu.Yu. et al. Protective structures of civil defense: Design and operation. - M.: Energoizdat, 1985, 232 pp.).

 In this device, if there is a possibility of the appearance of toxic substances in the outdoor air, the ventilation system is turned on and atmospheric air is supplied to the protective structure through one of the parallel-mounted filter absorbers until the breakthrough warning is triggered, indicating the presence of toxic substances vapors at the outlet of the filter. After that, the second filter-absorber is put into operation, and the previous one is replaced with a new one. Moreover, under the conditions of periodicity of the appearance of toxic substances, not only polluted atmospheric air, but also atmospheric air that does not contain vapors of toxic substances may enter the filtrate absorbers for some time. However, even in this case, various sorbing impurities (water vapor, organic impurities of artificial and natural origin) are contained in the atmospheric air, which are not hazardous to humans, nevertheless they are absorbed by the adsorbent of the filter-absorber, reducing the capacity of the filter mixture for the target component (in pairs toxic substances). Moreover, if the filter contained a previously sorbed toxic substance, then blowing through its charge of uncontaminated atmospheric air can cause desorption, which leads to the movement of the sorbate zone along the charge layer and premature appearance of toxic substance vapors at the filter outlet, while the sorption capacity of the adsorbent charge is used only partially. In addition, during the sorption process, the sorption front is smeared out due to a number of kinetic and diffusion factors (slow mass transfer processes, longitudinal, vortex, dynamic, and other types of diffusion), which leads to the appearance of the so-called working layer (mass transfer zone), which also reduces the degree of use of the sorption charge capacity.

 All this reduces the efficiency of using an expensive adsorbent and, as a result, the efficiency of the device as a whole.

 The problem solved by the proposed device is to increase the efficiency of the device due to the efficiency of use of the adsorbent.

 The problem is solved due to the fact that the device containing two parallel filter slots of the filter-absorber connected to the supply duct and the fan at the outlet, as well as a system of four pressure valves installed one at the input and output of each of the filter-absorbers a detector and an ejector, sequentially mounted on the supply duct to the pressure valves, and the reduced pressure chamber of the ejector is connected to the fan inlet using the newly introduced bypass air water through additionally placed and connected in series heat exchanger and a safety chamber with a heating element, additionally equipped with inlet and outlet pressure valves. In this case, the output of each filter-absorber is directly connected to the input of each other filter-absorber with additional sections of air ducts with pressure valves. In addition, the inlet of the ejector on the supply duct through a pressure valve is connected directly to the inlet of the reduced pressure chamber of the ejector, and a valve is installed directly at the outlet of the safety chamber to supply air from the protective structure. Moreover, on the supply duct in front of the detector, a gas flow rate sensor is installed, connected to an automatic control system containing a current frequency converter with the ability to control current and voltage values.

 New features of the claimed device are a detector and an ejector sequentially mounted on the supply duct to the pressure valves, a bypass duct connecting the reduced pressure chamber of the ejector to the fan inlet, a heat exchanger and a safety chamber, two pressure valves installed at the inlet and outlet of the safety chamber, additional sections of air ducts with pressure valves, connecting the output of each filter-absorber directly to the input of each other filter-absorber, pressure valve, with connecting the ejector inlet to the supply duct with the inlet of the reduced pressure chamber of the specified ejector, a valve for supplying air from the protective structure installed directly at the outlet of the safety chamber, a gas flow rate sensor mounted on the supply duct, an automatic control system connected to the gas flow sensor flow, current frequency converter with the ability to control the values of current and voltage, which is part of an automatic control system.

 Although the above characteristics are known separately, however, their combination, due to the above connections, allows you to get a super-total effect, which would not have come from a simple introduction of these signs. Thus, the claimed solution meets the criterion of "inventive step".

 In the proposed technical solution, atmospheric air that does not contain vapors of toxic substances passes through the air duct through the safety chamber and a number of other structural elements installed on it, entering the atmosphere of the protective structure.

 When toxic substances vapors appear at the inlet of the device (as evidenced by the detector installed on the supply duct), the contaminated air is supplied to one of the filter absorbers, and the safety chamber that was used before is regenerated in order to remove toxic substances vapors that got into it as a result the inertia of the response of the detector, and then its subsequent cooling to the initial temperature. The total cycle time of regeneration and cooling of the safety chamber is small compared with the operating time of the filter-absorber and depends mainly on the response time of the detector, on the characteristics of the adsorbent in the safety chamber and on the regeneration temperature determined by the type of adsorbent used.

 The above avoids purging through atmospheric air filters that do not contain vapors of toxic substances, which eliminates the possibility of desorption processes in the charge and clogging of the filter-absorber by adsorbed non-toxic impurities contained in atmospheric air.

где τ_c - время совместной работы фильтров-поглотителей, с;
l₀ - длина работающего слоя (длина зоны массопередачи), м;
U - скорость движения сорбционного фронта, м/с;
τ_з.д - время защитного действия, с;
l_ш - длина слоя шихты, м;
За время совместной работы происходит полная отработка шихты первого фильтра-поглотителя.When the maximum permissible concentration of toxic substance vapors appears at the outlet of the filter-absorber, the second filter-absorber is connected in series to the outlet of the first and for some time they work together. The time of joint work of filter-absorbers can be approximately calculated by the formula

where τ _c is the time of joint work of filter-absorbers, s;
l ₀ - the length of the working layer (the length of the mass transfer zone), m;
U is the speed of movement of the sorption front, m / s;
τ _W - the time of the protective action, s;
l _W - the length of the charge layer, m;
During the joint work, the charge of the first filter-absorber is completely worked out.

 Thus, the use of the proposed technical solution provides, in comparison with the prototype, adopted as the base object, higher efficiency of the use of the sorbent by eliminating the possibility of purging through atmospheric air filters that do not contain vapors of toxic substances, but containing other impurities (non-toxic sorbing), and also by eliminating the influence of blurring the front of the sorbate in the sorption process, which improves the efficiency of the device as a whole. Higher efficiency of use of the sorbent allows to reduce the stocks of filter-absorbers, which additionally entails the saving of usable area in protective structures.

 The drawing schematically shows the proposed device. The device consists of two parallel-mounted filter-absorbers 1 and 2, filled with a mixture of finely porous catalyst coal, equipped with breakthrough detectors 3. Filter-absorbers 1 and 2 are connected to a supply duct 4, a fan 5, installed at the outlet of the device, and equipped with pressure valves 6 , 7, 8, 9. A detector 10 (for example, a thermionic detector, characterized by increased sensitivity to phosphorus, nitrogen, and halogen-containing compounds) and an ejector 11, a pony chamber, are sequentially mounted on the supply duct the pressure of which is connected to the fan 5 using a newly introduced bypass duct 12 through a series-connected heat exchanger 13, a safety chamber 14, filled with a mixture of mesoporous adsorbent (for example, coal grade AP-3), equipped with a heating element 15 and pressure valves 16, 17, while the output of each filter-absorber is connected to the input of each other specified filter by a duct system with pressure valves 18, 19. In addition, the inlet of the ejector 11 on the supply duct 4 through the pressure valve 20 is connected chastkom duct from entering the low pressure chamber of said ejector 11 and the outlet chamber 14 of the safety valve 21 is installed to supply air from the protective structure.

 In addition, on the supply duct 4, in front of the detector 10, a gas flow rate sensor 22 is mounted, connected to an automatic control system 23, comprising a current frequency converter 24 with the ability to control current and voltage values.

 The device operates in two modes. In all modes, the detector 10 and fan 5 are continuously running.

 In the first mode (before the appearance of toxic substances vapors detected by the detector 10 at the input to the device), valve 21 and pressure valves 6, 7, 8, 9, 18, 19 are closed, and pressure valves 16, 17, 20 are open. The heat exchanger 13 and the heating element 15 of the safety chamber 14 are turned off. Atmospheric air through a fan 5 enters from the supply duct 4 to the room of the protective structure through the gas pipeline section with a pressure valve 20, bypassing the air duct 12 and the heat exchanger 13 installed on it, a safety chamber 14 with pressure valves 16, 17.

 In the second mode (after the appearance of vapors of toxic substances detected by the detector 10 at the input to the device), the device operates in two sub-modes.

 In the first submode (before the breakthrough warning 3 is triggered), contaminated atmospheric air is supplied to the fortification structure through one of two filter-absorbers (for example, through filter-absorber 1) using a fan 5. The choice of filter absorber 1 or 2 is arbitrary. Valve 21 and pressure valves 7, 9, 16 are open, and pressure valves 6, 8, 17, 18, 19, 20 are closed. The heating element 15 and the heat exchanger 13 are turned on. Due to the rarefaction created by the ejector 11 in the bypass duct 12, part of the air from the protective structure through the valve 21 enters the heated safety chamber 14, where desorption of toxic vapors that have fallen into it due to the inertia of operation detector 10. Then, the desorbing air is cooled in the heat exchanger 13 and mixed with the main stream of polluted air entering the filter absorber 1 from the supply duct 4. After the desorbent vapor is removed from the safety chamber 14, the heating element 15 is turned off and the chamber continues to be blown with air from the protective structure for some time, cooling to the initial temperature (to the air temperature in the building). Then, the valve 21 and the pressure valve 16 are closed.

 In the second submode (after the breakthrough indicator 3 of the filter-absorber 1 is activated), the pressure valves 7, 8, 19 are open, and 6, 9, 17, 18, 20 are closed. Valve 21 and pressure valve 16 can be either closed or open, depending on whether the regeneration and cooling cycle of the safety chamber 14 is completed or not. Polluted air is supplied to the fortification structure through two series-connected filter-absorbers 1 and 2.

After the time τ _{s has} elapsed since the leakage indicator of the filter-absorber 1 is activated, the pressure valves 7, 19 are closed and the pressure valve 6 is opened, providing contaminated air to the protective structure only through the filter-absorber 2. During operation of the filter-absorber 2, the filter-absorber is replaced 1 to a new one. Working with filter-absorber 2 is similar to working with filter-absorber 1 in all modes and sub-modes of the device.

 Throughout the entire time of operation at the input to the device, a constant flow of gas flow is maintained by means of a sensor 22 connected to an automatic control system 23, comprising a current frequency converter 24 with the ability to control current and voltage values.

 The above allows us to conclude that the proposed invention meets the criterion of "industrial applicability".

Claims (1)

 A device for purifying air from toxic substances, containing two filters absorber installed parallel to the warning devices connected to a supply duct and a fan at the outlet, as well as a system of four pressure valves installed one at the inlet and outlet of each filter absorber, characterized in that it is equipped with a detector and an ejector, sequentially mounted on the supply duct to the pressure valves, and in front of the detector there is a gas flow rate sensor connected to a a control system containing a current frequency converter with the ability to control current and voltage, and a reduced pressure chamber of the ejector is connected to the fan inlet using the introduced bypass duct through additionally placed and connected in series heat exchanger and safety chamber with a heating element, additionally equipped with an input and output pressure valves, while the output of each filter-absorber is directly connected to the input of dogo other filter-absorber duct with additional portions hermetic valves, in addition, input to the ejector through the supply duct germoklapan connected directly to the input of a low-pressure chamber of the ejector, but directly at the outlet of the safety valve chamber is mounted to the air supply of protective structure.