DE2139719A1 - Exhaust gas purificn - from solid, liq or gaseous components - Google Patents

Abstract

The gas purifier incorporates a passage chamber in which the exhaust gases come into contact with the wash liq. issuing through a number of nozzle jets arranged one after another. The jets have a conical liq. outlet with an opening angle of at least 90 degrees and impinge upon the inner walls of the chamber. The nozzles may also be built as sifting nozzles consisting of a hollow body with continuously decreasing inner cross section. The interior of the nozzles may be built as a closed hemispherical capsules with the jets located at the largest distance from the bottom surface. The inlet pipe for the gas is arranged tangentially so as to give a rotary motion to the gases.

Description

Device for separating solid, volatile and gaseous Components from exhaust gases and exhaust air quantities.

The invention relates to a device for separating solid, volatile and gaseous components from exhaust gases and quantities of exhaust air that enter the atmospheric air, consisting of a flow-through chamber in which the exhaust gases or exhaust air quantities are brought into contact with scrubbing liquid, those of several in the flow direction of the exhaust gases or exhaust air quantities one after the other lying jet nozzles are introduced into the flow-through chamber according to latent no. .... (patent application P 16 71 393.2-45).

In known devices of this type there is the difficulty the washing liquid over a sufficient period of time with the Bringing exhaust gases or quantities of exhaust air into contact, and both hot exhaust gases on one Lower temperature at which the precipitation of certain volatile components can occur in the first place and the absorption of the oil components to be excreted to enable. Known devices solve this problem only imperfectly because with these only brief contact with the exhaust gases or amounts of exhaust air the washing liquid takes place.

in the arrangement according to the main patent it is therefore provided that the jet nozzles are designed and arranged so that they are several in a row lying film-like and the passage cross-section of the flow-through chamber completely or produce largely filling veils of water, each of which is transverse to the main flow direction the exhaust gases or exhaust air quantities. It is provided that the beam direction at an angle in the direction of the flow of the exhaust gases or exhaust air.

This device already brings good long-term contact the exhaust gases or discharges, however, does not yet lead to a complete and complete one absorption of the Gestandteile to be separated A) he invention lies Accordingly, the object is based on the Vorricktung according to the main patent to keep it up improve that the most complete possible absorption of the components to be eliminated reached and the contact time of the washing liquid with the exhaust gases or exhaust air quantities is further enlarged.

According to the invention, this object is achieved in that the jet nozzles have a conical water outlet with an opening angle of at least 90 °, which is directed against the direction of flow of the exhaust gases or the quantities of exhaust air and impinges at its outer end on the inner wall of the flow-through chamber.

Alt this arrangement is achieved that the exhaust or, Alluitstro by contact with the conical water outlet, the direction of its flow counteracts being ungeled and thus at an angle against its direction of flow Inner wall @@, to which the pressure chamber is led.

In the case of the flue gas or exhaust air flow, the U @ -len. @@ conditional Turbulence through which the contact time with the Wasserstrabl or water veil is increased considerably and, in addition, the cooling of hot exhaust gases in the area of the nozzles initially acted upon by the exhaust gas or exhaust air flow is promoted. The components to be eliminated are together with the against the flow direction of the exhaust gas or exhaust air flow acting water jets or Veils of water against the walls of the Druchströmkamer, where they are, for example with vertical throughflow chamber downwards, all so against the direction of flow of the exhaust gas or exhaust air flow can flow off on its outside.

In a particularly advantageous trip, the conical water outlet becomes generated in that the Stralildüsen are designed as swirl nozzles, which consist of a hollow body with continuously decreasing horizontal internal cross-section exist, in which a central outlet opening for the water jet iii ßereicji of the smallest (cross section and a tangential supply line; in the area of the largest Cross-section is provided.

With such swirl nozzles, that of the swirl nozzle is through the supply line supplied water jet is set in a circular motion and at the same time through the continuous light Cross-sectional reduction is becoming more and more stylish, so that it emerges from the outlet opening in a circling manner and at high speed. There it forms a very rapidly rotating water cone, its individual elements move at high speed, in this way the redirection of the exhaust gas or exhaust air flow on a water cone formed in this way and thus filling the The components to be eliminated are guaranteed with a safety record.

in this case, the interior of the swirl nozzle is advantageously as closed Aalbkngelschale formed, in their function the greatest distance to the base the outlet opening for the water jet is appropriately common supply line to the straiildiisen arranged one behind the other in the area the wall of the flow-through chamber is arranged, with the straaldusen via short branch lines the supply line is connected and arranged axially to the flow-through chamber, the Invention is explained below with reference to an ilusf approximately example in the drawing explained in more detail.

Fig. 1 shows a section in a mechanical representation the device according to the invention.

FIG. 2 is section II-II according to FIG. 1.

Fig. 3 shows in section one of the swirl nozzles.

FIG. 4 is section IV-IV according to FIG. 3.

In Figure 1, a vertical hollow cylindrical is in section Through-flow chamber 1 shown, in which axially one above the other several as swirl nozzles trained jet nozzles 2 are arranged. The jet nozzles 2 are with supply lines 3, which are connected to a common line 4. The line 4 can use a pump 5 from a basin 6 the necessary cleaning water are supplied, the basin 6 being separated from a clarifier 8 by a filter 7 is separated, which is to be separated via a funnel 9 and a discharge line 10 Components are added.

The hbgas- or exhaust air flow is the flow-through chamber 1 from below fed via a line 11 in the direction of arrow 12 and in the direction of arrow it deflected 13 upwards. A water cone 14 emerges from each of the swirl nozzles 2 consisting of sharp water jets rotating in a sclinel and an opening angle of at least 90 °.

This water cone is against the direction of flow of the exhaust gases or of the exhaust air is directed downwards in the l!

The outer ends of the water cone 14 meet the inner wall la of the flow-through chamber 1, so that the components to be precipitated on the inside of the water cone 14 fed to the walls la of the flow chamber 1 and against the direction of flow of the exhaust gases or the quantities of exhaust air in the direction of the arrows 15 are guided down and thus get into the clarifier 8, Fig. 2 is the Section II-II according to FIG. 1 and leaves the position of the supply line 4 as well as in @Cross section the branch line 3 in connection with the nozzle 2. The arrows 1G illustrate the rotating water jets and the deflection caused by the rotation of the Water streaks 16, while the arrows 17 indicate the scotation direction indicate.

Fig. 3 shows in section one of the swirl nozzles 2, which as a closed llalbkugelschale are formed, so that they have a continuously decreasing size have a horizontal internal cross-section. A central outlet opening 18 for the water jets 16 is located in the area of the smallest cross section, i.e. at the point of greatest distance to the base 19 of the interior of the swirl nozzle 2. ie indicated by 20, the initially through the line 3 which opens tangentially into the nozzle 2 set in rotation and then as a result of the continuously decreasing cross-section accelerated more and more, so that the water jets 16 at high speed exit from the outlet opening 18 and there the rapidly rotating water cone form.

Fig. 4 is the section IV-IV after lig. 3 and leaves in particular the tangential confluence of the supply line 5 to the nozzles 2 and the initial direction of flow 21 Detecting the supplied ilassers0 A particularly complete one. Separation of the constituents to be removed from the gases can thereby be achieved that the gas to be cleaned or the one to be cleaned. Exhaust air into the flow-through chamber 1 nash Fig. 1 is introduced tangentially and thus a rotational movement accordingly executes the arrow 13 in Fig. 1 in the flow-through chamber, this rotational movement is favored with a cross-section of the flow-through chamber.

It is particularly advantageous if the direction of rotation of the entering Exhaust gas or the exhaust air with the direction of rotation of the water jets emerging from the nozzles 2 agrees, because beer creates a particularly intimate long-term contact between the exhaust gas bst. the exhaust air and the water is brought about. Regardless of it is ca, however, it is also possible to rotate in the opposite direction in the exhaust air or exhaust gas the direction of the water flow, causing turbulence in the exhaust gas or Exhaust air and the water streams arise, which for certain elimination conditions can be beneficial.

Claims (6)

Expectations Device for separating solid, volatile and gaseous Components from exhaust gases and waste quantities discharged into the atmospheric air consisting of a flow-through chamber in which the exhaust gases or exhaust air quantities be brought into contact with washing liquid, consisting of several in the flow direction of the exhaust gases or exhaust air quantities one behind the other into the flow-through chamber is initiated according to patent no. ... (patent application P 16 71 393.2-45), thereby characterized in that the jet nozzles (2) have a conical water outlet (14) with an opening angle of at least 900, which is against the direction of flow (13) the exhaust gases or the amount of exhaust air is directed and at its outer end the inner wall (la) of the flow chamber (1) strikes. 2. Apparatus according to claim 1, characterized in that the jet nozzles (2) are designed as swirl nozzles, which consist of a hollow body with it continuously small: nem horizontal internal cross-section, in which a central Outlet opening (18) for the water jets (16) in the area of the smallest cross section and a tangential feed line (3) is provided in the area of the largest undercut is. 3. Apparatus according to claim 2, characterized in that the interior the swirl nozzle (2) is designed as a closed iialbsugelschale, in the point The outlet opening (18) for the water jets is at the greatest distance from the base (19) (1G) is located. 4. Device according to one of the preceding claims, characterized in that that the common supply line (4) to the jet nozzle (2) in the area of the wall (ia) the flow-through chamber (i) is arranged and that the jet nozzles (2) over short Branch lines (3) connected to the supply line (4) and centered on the axis to the throughflow chamber (i) are arranged. 5. Device according to one of the preceding claims, d a d u r c h g e k e n n n n e i c h n e t that the inflow line (11) for the exhaust gas or the amount of exhaust air in the flow-through chamber (i) tangential to the cross section of the Durehst rörkcuzer (i) is directed and the exhaust gas or the exhaust air quantity in a hotation movement offset, 6. Apparatus according to claim 5, characterized in that the direction of rotation (13) of the exhaust gases or the exhaust air flow in the direction of rotation (17) of the jet nozzles (2) exiting water jets (16) überingtizxt. L e r s e i t e