RU57632U1 - DEVICE FOR CLEANING EXHAUST GASES - Google Patents

Abstract

The invention relates to a device for cleaning exhaust gases, preferably exhaust gases of diesel engines installed on ships, locomotives, etc.

A device for purifying exhaust gases is proposed, comprising a pipeline for supplying purified gases, a reaction chamber with spray heads for spraying water in the volume of the reaction chamber, a channel for removing purified gases and a channel for removing water with absorbed impurities, in which according to the invention there are two rows of guide vanes installed in the reaction chamber and providing for swirling the stream of gas to be purified and water jets in the volume of the reaction chamber. This provides an increase in time and contact area of the gas to be cleaned and water jets and, accordingly, an increase in the cleaning efficiency.

Description

The invention relates to a device for cleaning exhaust gases, preferably exhaust gases of diesel engines installed on ships, locomotives, etc.

Diesel engines of ships are known to be the main pollutants of the surrounding air. According to studies in the United States, 14% of the world's nitrogen oxide emissions and 16% of sulfur oxides in exhaust gases are related to shipping. Most of the nitrogen oxides from diesel engines are emitted when the engines operate at reduced power, as is the case when the ship is in port.

A device for cleaning the exhaust gas of diesel internal combustion engines, comprising a pipeline for supplying combustible gas and a chamber for liquid cooling and purification of exhaust gases with mounted heads for spraying water under pressure (see patent RU 2124456 C1, 63 G 8/12 , B 63 H 21/32, F 28 D 3/00, 1999). The disadvantage of this device is its large dimensions and relatively large resistance to the flow of the purified gas.

The closest in technical essence to the proposed device is a device for purification of exhaust gases, containing a pipe for supplying a cleaned gas, a reaction chamber mounted coaxially inside a pipe for supplying a cleaned gas, a channel for outputting purified gas coaxially mounted inside the reaction chamber, guide vanes fixed on the outer surface of the channel for the withdrawal of purified gas facing the inner volume of the reaction chamber, a transverse annular partition overlapping pipeline for supplying the gas to be cleaned from the side opposite to its entrance and hermetically connected to the walls of the pipeline for supplying the gas to be cleaned and the walls of the channel for outputting the purified gas, spray heads for spraying water in the volume of the reaction chamber mounted at the inlet of the reaction chamber connected to the internal volume a pipeline for supplying a purified gas, a pipeline for draining water that has absorbed toxic impurities and solid particles contained in the exhaust gas, connected to the outlet of the reaction oh camera from the opposite direction

the removal of purified gas and placed coaxially to the channel for removal of purified gas (see RF patent No. 2270051, 01 D 53/92, 2006).

The known device adopted for the prototype has small dimensions and practically does not create aerodynamic resistance to the flow of the gas to be cleaned. On the contrary, due to the ejecting action of the spray heads spraying water at the entrance to the reaction chamber, a vacuum is created in the reaction chamber that draws in a cleaned stream of exhaust gases into the reaction chamber.

The disadvantage of the prototype is that the stream of gas to be cleaned, flowing along the inner wall of the reaction chamber, is subjected to a shorter exposure to water jets compared to the gas stream, flowing along the surface of the channel for outputting purified gas and experiencing deviation under the action of the guide vanes. As a result, the efficiency of exhaust gas cleaning is reduced, in particular, with respect to small (aerosol) soot particles contained in a gas stream flowing along a smooth surface of the inner wall of the reaction chamber.

The objective of the utility model was to increase the time and contact surface of the entire stream of gas to be cleaned with water jets in the volume of the reaction chamber.

This problem is solved by the fact that the proposed device for purification of exhaust gases, containing a pipeline for supplying a cleaned gas, a reaction chamber mounted coaxially inside a pipeline for supplying a cleaned gas, a channel for outputting purified gas, mounted coaxially inside the reaction chamber, guide vanes mounted on an external the surface of the channel for the withdrawal of purified gas, facing the internal volume of the reaction chamber, a transverse annular partition blocking the pipeline for supplying gas from the side opposite to its entrance and hermetically connected to the walls of the pipeline for supplying the gas to be cleaned and the walls of the channel for outputting the purified gas, spray heads for spraying water in the volume of the reaction chamber installed at the inlet of the reaction chamber connected to the internal volume of the pipeline for supplying the gas to be cleaned , a pipe for draining water that has absorbed toxic impurities and solid particles contained in the exhaust gas, connected to the outlet of the reaction chamber from the opposite side hydrochloric direction of discharging purified gas and disposed coaxially with a duct for discharging the purified gas, which according to the invention provided with a second guiding system

blades mounted on the inner surface of the reaction chamber facing the channel for outputting purified gases, and the guide blades mounted on the inner surface of the reaction chamber are displaced in the annular space of the reaction chamber relative to the guide blades mounted on the outer surface of the channel for outputting the purified gas.

Due to the presence of a second row of guide vanes mounted on the outer surface of the reaction chamber, the stream of gas to be cleaned is twisted in the annular space of the reaction chamber and its time and surface of contact with jets of water sprayed by spray heads increase. As a result, the cleaning efficiency of the exhaust gases increases.

In a preferred embodiment, the guide vanes are in the form of a screw surface.

Another difference of the proposed device is that it is equipped with sources of ultrasonic vibrations installed in the space of transition of the stream of gas to be purified from the pipeline for supplying the gas to be cleaned into the reaction chamber and mounted on a transverse annular partition blocking the pipeline for supplying the gas to be purified. Under the action of ultrasound, small soot particles are conglomerated into larger formations, which facilitates their capture by water jets.

Thus, the technical result of the utility model is to increase the time and contact surface of toxic impurities and particulate matter of the exhaust gas with water jets. This provides improved cleaning performance.

The invention is illustrated by drawings.

Figure 1 shows a longitudinal section of the proposed device.

In Fig.2 presents a view of the device in section along aa of Fig.1.

Figure 3 shows a device with a partial cutaway. An exhaust gas purification device comprises a pipe 1 for supplying a gas to be purified, a reaction chamber 2 mounted coaxially inside a pipe 1 for supplying a gas to be purified, a channel 3 for outputting a purified gas coaxially mounted inside the reaction chamber 2, and a transverse annular partition 4 blocking the pipe 1 for supplying the cleaned gas from the side opposite to its entrance and hermetically connected to the walls of the pipeline 1 for supplying the cleaned gas. On the outer surface of channel 3 for output

guided blades 5 are fixed to the purified gas facing the internal volume of the reaction chamber 2. Guiding blades 6 similar in shape are fixed to the inner surface of the reaction chamber 2 facing the channel 3 for outputting the purified gas. In this case, the guide vanes 6 in the space of the annular channel of the reaction chamber 2 are displaced relative to the guide vanes 5 in the direction of swirling the gas flow (shown by arrows in figure 2). In a preferred embodiment, the outer surface of the guide vanes 5 and 6 has the shape of a screw surface (see FIG. 3). The device is equipped with spray heads 7 for spraying water in the volume of the reaction chamber 2, mounted at the inlet of the reaction chamber 2 and mounted on an annular transverse partition 4. The outlet of the reaction chamber 2 is provided with a pipe for the output of water that has absorbed toxic impurities and solid particles (soot particles), contained in the exhaust gas. The pipeline 8 is placed coaxially to the channel 3 for the output of the purified gas. The device is also equipped with sources 9 of ultrasonic vibrations installed in the space of the gas to be purified from the pipeline 1 for supplying the gas to be cleaned into the reaction chamber 2 and mounted on an annular transverse partition 4. The spray heads 7 are connected to a system for supplying water under pressure (not shown in FIG. ) and are uniformly distributed throughout the entire annular volume at the inlet of the reaction chamber 2.

The device operates as follows.

The cleaned exhaust gases enter the device through a pipeline 1, which is directly connected to the exhaust gas source, for example, with the output of a diesel internal combustion engine. The cleaned gases are deflected by an annular transverse partition 4 and enter the inlet of the reaction chamber 2 where they are exposed to jets of water sprayed by the spray heads 7. The ejection effect of the spray heads 7 causes the cleaned exhaust gases to be sucked into the volume of the reaction chamber 2, where impurities CO, NO _X , SO ₂ and soot particles interact with the smallest drops (200 microns or less) of water. This interaction leads to the absorption of these impurities by water. The gas flow together with the water jets in the annular volume of the reaction chamber 2 is twisted using the guide vanes 5 and 6. This leads to an increase in the contact surface and the contact time of the gas stream to be cleaned with tiny drops of water, which increases the cleaning efficiency. Efficiency

cleaning in the proposed device is also increased due to the fact that under the action of ultrasonic vibrations generated by sources of 9 ultrasonic vibrations, the smallest soot particles conglomerate at the entrance to the reaction chamber 2 into larger formations that are effectively captured by water droplets. At the outlet of the reaction chamber 2, water that has absorbed toxic impurities and soot particles is discharged through a pipe 8 from the reaction chamber and enters the regeneration system (not shown in Fig.), And the gas purified from impurities is discharged through the channel 3 into the atmosphere.

Claims (3)

1. An exhaust gas purification device comprising a pipe for supplying a gas to be purified, a reaction chamber mounted coaxially inside a pipe for supplying a gas to be purified, a channel for discharging purified gas coaxially mounted inside the reaction chamber, guide vanes fixed to an outer surface of the channel for discharging purified gas gas, facing the internal volume of the reaction chamber, a transverse annular partition blocking the pipeline for supplying the gas to be cleaned from the side opposite to its entrance and hermetically connected to the walls of the pipeline for supplying purified gas and the walls of the channel for outputting purified gas, spray heads for spraying water in the volume of the reaction chamber installed at the inlet of the reaction chamber connected to the internal volume of the pipeline for supplying purified gas, a pipeline for draining water, absorbing toxic impurities and solid particles contained in the exhaust gas, connected to the outlet of the reaction chamber from the side opposite to the direction of removal of the purified gas, exl characterized in that it is equipped with a second system of guide vanes mounted on the inner surface of the reaction chamber facing the channel for outputting purified gas, and the guide vanes mounted on the inner surface of the reaction chamber are displaced in the annular space of the reaction chamber relative to the guide vanes mounted on the outer surface channel for the output of purified gas. 2. The device according to claim 1, characterized in that the guide vanes are in the form of a screw surface. 3. The device according to claim 1 or 2, characterized in that it is equipped with sources of ultrasonic vibrations installed in the space of transition of the stream of gas to be cleaned from the pipeline for supplying the gas to be cleaned into the reaction chamber and mounted on a transverse annular partition blocking the pipeline for supplying the gas to be purified.