RU2473378C2 - System for neutralisation of light and heavy toxic gases at danger of depressurisation of their containers - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: proposed system comprises tank for neutralisation solution and neutralising fluid circulation line with pump and ejector. Sarcophagus for containers with toxic gas accommodating container opening mechanism secured there inside is mounted at toxic gas feed line inlet. Solution solid, fluid and gas component feed assembly is mounted art tank for neutralisation solution and consists of pipeline, funnel and ejector with shutoff valves intended for tank sealing. Tank gas chamber has gas pressure gage and is communicated with sarcophagus via pipeline with gate valve and check valve. Toxic gas ejection suction pipeline is equipped with valve to control amount of toxic gases to be fed into ejector and toxic gas content pickup communicated with concentration metre. Said sarcophagus accommodates toxic gas ejection suction pipeline with suction inlet arranged nearby bottom for toxic gases heavier than air and nearby top for gases lighter than air.

EFFECT: mobile system, complete tightness on opening and neutralisation, safety and manufacturability.

2 dwg

Description

The invention relates to the field of neutralization of toxic gases and can be used to neutralize toxic gases in storage or field conditions due to the expiration of their storage periods, the danger of depressurization of containers used for their storage or in other emergency situations that could result in harm to human health and environmental contamination.

Known adsorption and absorption devices for neutralizing toxic gases and mass transfer apparatuses used for these purposes (Chemical Encyclopedia, vol. 1, M., 1992, pp. 4-14, 52-62 and T.3, M., 1992, pp. 335-339). Adsorption devices for neutralizing toxic gases - adsorbers, where solid media (technical activated carbons) are used as adsorbent, are considered to be quite effective in terms of degree of neutralization, but have significant drawbacks: they are not technological because they require large volumes of adsorbents, respectively, the dimensions of this equipment very significant, and after regeneration of the adsorbent toxic gas may again be released and the task of neutralizing it again arises.

Absorption devices for neutralizing toxic gases - absorbers or packed columns, are traditionally used in standard projects where various solutions (NaOH, Na ₂ CO ₃ , Ca (OH) ₂ , CaCO ₃ , etc.) are used as absorbent. In a packed column, a toxic gas absorbing solution (NaOH, Na ₂ CO ₃ ) is supplied to the nozzle from above through a distributor, and toxic gas is supplied from below from a countercurrent flow. In the collision of gas and liquid flows on the developed surface of the nozzle moistened with absorbing liquid, gas and liquid interact, resulting in its neutralization (absorption by the solution), and the absorbing solution flows into the drain chamber and is removed from the column. The nozzle column for gas purification contains a housing with nozzles for input and output of gas and liquid, a group of supporting grids on which nozzles are placed, a distributor and redistributors of liquid, and a liquid discharge chamber.

However, such devices have the following significant drawbacks - they are not technologically advanced due to the fact that they do not provide complete neutralization of accidental chlorine emissions, since the packed column must be filled with an absorption solution at startup, which takes considerable time and aggravates the results of the accident. Secondly, when supplying chlorine to the column, the nozzle requires putting it into operation, i.e. ensure uniform film flow of fluid along the surface of the nozzle. Therefore, in the initial period of the start-up of the column, a leakage of chlorine occurs, with a maximum concentration. In addition, the packed column is excessively bulky, requires a complex piping scheme, and occupies a large space.

The closest in technical essence and the achieved result is a method and device for neutralizing accidental emissions of chlorine (RF patent for the invention No. 2367506, priority dated 09.26.2007), implemented in LPG installations for neutralizing accidental emissions of chlorine, which are produced by FSP KRAVT LLC and are operated on the water utilities of Russia.

This chlorine neutralization device completely eliminates the leakage of toxic chlorine gas in the initial start-up period, providing it into the absorbing solution from the first minutes of the accident, therefore, no additional time is required for preparation and start-up, i.e. the process is inertialess, and this ensures the completeness of neutralization, however, the following significant disadvantages occur.

This device does not provide a safe opening unit for containers with toxic gas, which does not preclude its distribution in the room and the environment, and does not ensure the effectiveness of neutralization quality control by measuring the gas pressure in confined spaces, the flow rate of the ejected gas flow and the concentration of toxic gas in it, which when neutralizing a large number of containers with toxic gas, it can harm human health and have environmental negative consequences, and the absence of an external pumping system air as neutralization of toxic gas and the transition of its chemical components from gas-air cavities to the solution due to chemical interaction and the subsystem for equalizing gas pressures in these cavities will reduce the efficiency of ejection.

The technical result of the invention is to ensure the tightness of the device from the moment the container with toxic gas is opened until the neutralization process is completed, its current control using measuring devices, as well as the high efficiency of the ejection process due to pressure equalization in the sealed cavities of the device using check valves.

The technical result is achieved by the fact that the neutralization system for light and heavy toxic gases in the presence of a danger of depressurization of the containers used for their storage contains a neutralizing solution tank, a neutralizing liquid circulation line, which includes a pump and an ejector built into the toxic gas supply line, and at the entrance of the toxic gas supply line, a sarcophagus for a container with toxic gas is installed on a separate platform, having a gas pressure gauge and a lid on the inside to the side of which the opening mechanism of the container with an electric drive is attached, giving a rotary and reciprocating movement to the cartridge with a cutting tool fixed in it, and the reciprocating movement is carried out within a distance sufficient to open the through hole in the wall of the container of toxic gas with the lid closed, with controlling this movement with a switch installed outside the sarcophagus on the power line, and on the neutralizer tank, also installed on a separate platform, a unit for introducing solution components in solid, liquid and gaseous state is mounted, consisting of a pipeline, funnel and ejector with valves for shutting off their cross-sections for sealing the tank, the gas cavity of the tank having a gas pressure gauge and connected to the sarcophagus by a pipeline with a valve and a check valve; on the pipeline for ejection suction of toxic gases, a valve is installed to regulate their quantity supplied to the ejector, and a sensor for the content of toxic gases in the flow connected to a meter for their concentration, and finally in the sarcophagus the pipeline for ejection suction of toxic gases ends with a nozzle whose suction inlet is set for toxic gases heavier air - at the floor, and for toxic gases lighter than air - at the ceiling of the sarcophagus.

Figure 1 and figure 2 shows the inventive device, General view.

The composition of the device includes a platform of the catalyst 1 with a tank 2 installed on it with a neutralizing solution 3, over which a gas-air cavity 4 is kept. A circulation line 5 with a pump 6 is introduced into the solution, closed through valve 7, the main ejector 8 and the ejector pipe 9 to the gas-air cavity 4 for returning the flow of the neutralizing solution to the tank 2, in the lower part of which a drain valve 10 is installed, and on the upper surface there is an auxiliary ejector 11 for introducing gaseous or liquid components of the neutralizing p a solution with a pipe 12, a valve 13 on the circulation line of the prepared solution and a valve 14 on the input line of gaseous or liquid components, a valve with a fitting 15 for supplying water to the tank 2 and a valve with a shutter 16 for introducing solid bulk components into the solution, and on the upper surface a pressure gauge 17 for measuring the pressure in the gas-air cavity 4 and a check valve 18 that releases the gas-air mixture from the cavity 4 and connected to the pipeline 19 for supplying the gas-air mixture from the cavity 4 through the valve 20 to the sar kofag 21 installed on its own platform 22, in which a container 25 with toxic gas is laid and fixed on a support 23 with fasteners 24, and on its cover 26, when neutralizing gases, it is lighter than air (Fig. 1) or on the bottom of the sarcophagus 21 when neutralizing gases it is heavier air (figure 2) from the inside, the opening mechanism of the container 27 with an electric drive and a cutting tool 28 in the cartridge 29 is strengthened, which is controlled by an electric switch 30 located outside the sarcophagus 21. A pressure gauge 32 for measuring gas pressure in this cavity is introduced into the cavity 31 of the sarcophagus 21 pa tubes 33 for ejection of toxic gas from the cavity 31, the suction inlet of which is installed in the lower part of the cavity 31 when neutralizing toxic gases is heavier than air or in its upper part if the toxic gas is lighter than air, and the pipe 33 at the outlet of the sarcophagus 21 is connected to the ejection pumping pipeline 34, on which the valve 35, the flow meter 36 and the toxic gas content sensor in the stream 37, which provides a signal to the toxic gas content meter 38, moving under the influence of ejection through the pipe 34 connected to the ejector input of the main ejector 8. To replenish the gas pressure in the cavity 4 on the upper surface of the tank 2 there is a check valve 39 with a valve 40.

The device operates as follows.

The device is delivered on platform 1 and platform 22 to the site of neutralization of packaged toxic gases in order to prevent excessive tipping and movement of containers with toxic gases due to its possible unauthorized opening. From this moment, the technological process of neutralizing packaged toxic gases begins, and the full cycle of neutralizing toxic gas in a sealed container consists of the following sequentially performed procedures.

In the initial state, all valves and the shutter 16 of the device must be closed.

The neutralizing solution is either prepared in advance and poured into the tank 2 through a nozzle with a valve 15 open for these purposes, or prepared on the spot by introducing liquid components, including water, through the same nozzle with a valve 15, bulk through a funnel with an open shutter 16 and gaseous and possibly some liquid - with the help of an auxiliary ejector 11 and an open valve 14 when pre-filling water and main liquid components into the tank 2 and pumping them through the pump 6 through the pipe 12 with the valve 13 open.

At the end of the process of preparing the solution, the pump 6 is turned off, the valves 13, 14, 15 and the shutter 16 are closed, ensuring the tightness of the cavity 4 and the tank 2, and the stage of preparing the sarcophagus 21 for work begins. For this, with the lid of the sarcophagus 25 open, the container with toxic gas moves from the storage location to the sarcophagus 21, fits onto the support 23, is fixed on it in the required position and is fastened with fasteners 24. Then the lid 26 is tightly closed, ensuring tightness with closed valves 20, 35 sarcophagus 21. Next, using the switch 30, the opening mechanism of the container 27 is turned on, the electric drive of which ensures the rotation of the cutting tool 29 and its movement together with the cartridge 29 towards the wall of the container 25, opening through tverstiya and return it to its original state. The release of toxic gas from the hole formed leads to an increase in pressure in the cavity 31, which is recorded by the pressure gauge 32 and is a signal to start the process of neutralizing the toxic gas that has left the container 25 and into the cavity 31.

To implement this process, open valves 7, 20, 35, 40 and, with the valve 12 closed, turn on the pump 6, which circulates the neutralizing solution 3 in a closed circuit: tank 2 - pipe 5 - valve 7 - main ejector 8 - ejector pipe 9 - tank 2 At the same time, a suction effect is created in the ejection inlet of the main ejector 8, due to which toxic gas from the cavity 31 of the sarcophagus 21 moves along the pipe 33, valve 35, flow meter 36, pipeline 34 and sensor 37 into the main ejector 8, where it is not mixed with the flow neutralizing solution, and the process of its neutralization begins, due to sorption and (or) chemisorption, which almost ends at the outlet of the main ejector pipe 9, due to its sufficient length, and when the spent solution falls on the solution surface in the tank 2 in the gas-air cavity 4 it is mainly delayed trapped air in the cavity 31 with the toxic gas and partly unreacted toxic gas with acceptable solution. The increase in the pressure of the gas-air mixture in the cavity 4 is fixed by a manometer 17, and through the check valve 18, the pipeline 19 and the open valve 20, the gases flow from the cavity 4 to the cavity 31 if their pressure in the cavity 4 exceeds the pressure in the cavity 31. The process will continue until while the readings of the meter of toxic gas content in stream 37 are not reduced to an acceptable level (MPC), and the readings of pressure gauges 17 and 32 will not have equal values. If these values are lower than the atmospheric pressure at the location of the device, then the check valve 39 will open and through the valve 40 into the cavity 4, and therefore into the cavity 31 through the check valve 18, the valve 20 and the pipe 19 will be additional atmospheric air to equalize the pressure in these cavities with atmospheric pressure. And as a result, practically only air should remain in cavity 31 and cavity 4. These factors are evidence of the completion of the process of neutralizing the toxic gas in the container 24.

At the end of the process of neutralizing toxic gas, close the valves 20 and 35, open one of the valves on the upper surface of the tank 3 and open the valve 10 to drain the spent solution from the tank 2. Then close the valve 10 and one of the open valves on the upper surface of the tank 3. The lid opens the sarcophagus 26 and from the sarcophagus 21 the container 25 freed from toxic gas is withdrawn. This completes the full cycle of neutralizing light and heavy toxic gases in the face of the danger of depressurization used for their storage of containers.

The composition of the neutralizing solution, capable of neutralizing the required toxic gas under ejection mixing conditions, and its amount are determined for each case of neutralization based on theoretical information and experimental studies. So, to neutralize gaseous chlorine, it is advisable to use the composition of the solution used in LPG plants to neutralize accidental emissions of chlorine (RF patent for the invention No. 2367506, priority from 09.26.2007), namely:

sodium hydroxide (NaOH) 10-15 (wt.%) sodium thiosulfate (Na ₂ S ₂ O ₃ ) 3-10 (wt.%)

The use of the inventive system to neutralize packaged toxic gases provides, in comparison with the prototype, the mobility of the system, the complete tightness of the process of opening containers and the neutralization of toxic gas, which guarantees safety for people and the environment, as well as ensures high adaptability of the device.

Claims (1)

A system for neutralizing toxic gas of light or heavy, containing a tank for a neutralizing solution, a line for circulating a neutralizing liquid, which includes a pump and an ejector integrated with a suction inlet to the toxic gas supply line, characterized in that the sarcophagus is installed at the entrance of the toxic gas supply line for containers with toxic gas, having a pressure gauge for measuring gas pressure, in the lid of which, on its inner side, the opening mechanism of the container, consisting of a cartridge with m cutting tool with electric drive of its rotational and reciprocating movement within a distance sufficient to open the through hole in the wall of the container of toxic gas with a sealed lid closed, outside the sarcophagus on the power line there is a switch for controlling the movement of the cutting tool, the tank for neutralizing liquid is installed on a separate platform and on it is mounted a node for input of the components of the solution in solid, liquid and gaseous state, consisting of a pipeline, a raven and an ejector with valves for shutting off their passage sections to seal the tank, and on the surface of the tank for neutralizing liquid there is a pressure gauge for measuring the gas pressure in the gas chamber of the tank, which is connected to the sarcophagus by a pipeline with a valve and a non-return valve, and a control valve is installed on the pipeline for ejection of toxic gases their quantity supplied to the ejector, and a sensor for the content of toxic gases in the stream, connected to a meter for their concentration, while the sarcophagus and EET conduit ejection pumping toxic gases to the nozzle, the suction inlet of which is mounted near the floor of the sarcophagus for toxic gases heavier than air, or - the sarcophagus ceiling for toxic gases lighter than air.

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