DE2139719C3 - Wet scrubber for separating solid, volatile and gaseous components from exhaust gases or exhaust air - Google Patents

Description

The invention relates to a wet washer for Separation of solid, volatile and gaseous components from exhaust gases or exhaust air, consisting of a Through-flow chamber in which the exhaust gases are brought into contact with the washing liquid by several flat jet nozzles one behind the other in the flow direction of the exhaust gases in the flow-through chamber create a veil of water that fills the cross-section of the passage and is predominantly transverse to the main flow direction the exhaust gases hit the opposite side of the flow-through chamber, according to patent 16 71 393.

In known devices of this type there is the difficulty of the washing liquid over a sufficient Time to bring both exhaust gases into contact with the exhaust gases or amounts of exhaust air to cool down a temperature at which the filling of certain volatile components in the first place can occur and to enable the absorption of the components to be excreted. Known devices solve this task only imperfectly, since with these only a very brief contact with the exhaust gases

ίο or amounts of exhaust air taking place with the washing liquid.

In the arrangement according to the main patent is therefore

provided that each jet nozzle designed as a flat jet nozzle to change the angle at which the Water veil meets the wall of the flow-through chamber, is arranged rotatably.

This device already brings a good long-term contact with the exhaust gases, but leads does not yet lead to a complete and complete absorption of the components to be eliminated.

The invention is accordingly based on the object of continuing the wet washer according to the main patent to improve that the complete absorption of the components to be excreted is achieved and the Contact time of the scrubbing liquid with the exhaust gases is further increased.

This object is achieved in that each jet nozzle has a water cone with a Generated opening angle of at least 90 °, the water cone against the flow direction of the exhaust gases is directed

With this arrangement it is achieved that the exhaust gases counteract their flow direction through contact with the water cone, deflect them and thus lead them at an angle against their flow direction to the inner wall of the throughflow chamber. Turbulence caused by the deflection occurs in the exhaust gases, which considerably increases the contact time with the water curtain and also significantly promotes the cooling of hot exhaust gases in the area of the jet nozzles initially acted upon by the exhaust gases. The components to be separated out are guided against the inner wall of the flow chamber together with the water veil acting against the flow direction of the exhaust gases, where they can flow downwards, for example, against the flow direction of the exhaust gases on the inner wall when the flow chamber is vertical.
In a particularly advantageous manner, the water cone is generated in that the jet nozzles are designed as swirl nozzles, which consist of a hollow body with a continuously decreasing horizontal inner cross-section, in which a central outlet opening for the water jet in the area of the smallest cross-section and a tangential supply line in the area of the largest cross-section is provided. With such swirl nozzles, the water jet fed to the swirl nozzle through the supply line is set in a circular motion and at the same time accelerated more and more by the continuous reduction in cross-section, so that it exits the outlet opening in a circular manner and at high speed. There it forms a very rapidly rotating water cone, the individual elements of which move at a higher rate

^ft 5 speed move. In this way, the deflection of the exhaust gases at a cone of water formed in this way and thus the filling of the components to be eliminated is guaranteed with certainty.

In this case, the interior is advantageously the Impact nozzle designed as a closed hemispherical shell, at the point of which the greatest distance to the base area is the outlet opening for the water jet is located

The common feed line to the jet nozzles arranged one behind the other is expediently in the Arranged in the area of the wall of the flow-through chamber, the jet nozzles via short branch lines are connected to the supply line and arranged axially to the flow chamber.

The invention is explained in more detail below using an exemplary embodiment in the drawing.

F i g. 1 shows, in section, a schematic representation of an embodiment of the wet washer according to the invention.

F i g. 2 is the section H-II according to FIG. 1.

F i g. 3 shows one of the swirl nozzles in section.

F i g. 4 is section IV-IV according to FIG. 3.

In Fig. 1, a vertical hollow cylindrical flow chamber 1 is shown in section, in which are centered on each other as swirl nozzles trained jet nozzles 2 arranged si <d. The jet nozzles 2 are provided with branch lines 3, soft are connected to a common supply line 4. The supply line 4 can be made by means of a pump 5 a basin 6 the necessary cleaning water are supplied, the basin 6 by a Filter 7 is separated from a clarifier 8, which via a funnel 9 and a drain line 10 the Components to be eliminated are supplied.

The exhaust gases enter the flow-through chamber 1 from below via a line 11 in the direction of the arrow 12 fed and deflected in the direction of arrow 13 upwards. From the swirl nozzles 2 occurs in each case Water cone 14, which consists of rapidly rotating sharp water jets and an opening angle of at least 90 ° This water cone is directed downwards against the flow direction of the exhaust gases

The outer ends of the water cone 14 hit the inner wall in the flow-through chamber 1, see above that the components to be precipitated on the inside of the water cone 14, the walls la of the flow-through chamber 1 and against the direction of flow of the exhaust gases in the direction of arrows 15 after are guided down and thus get into the clarifier 8.

Fig.2 is the section H-II of FIG. 1 and leaves in Recognize the cross-section of the position of the supply line 4 and the branch line 3 following the nozzle 2. the Arrows 16 illustrate the rotating water jets and the deflection of the caused by the rotation Water jets 16, while the arrows 17 indicate the direction of rotation.

3 shows in section one of the swirl nozzles 2, which as closed hemispherical shell are formed, so that they have a continuously decreasing horizontal

have in internal cross-section. A central outlet 18 for the water jets 16 is located in the area of the smallest cross section, that is to say in the largest point Distance to the base 19 of the interior of the swirl nozzle 2. As indicated by 20, this is through the Tangentially into the nozzle 2 opening branch line 3 supplied water initially set in rotation and then accelerated more and more as a result of the continuously decreasing cross-section, so that the Water jets 16 emerge at high speed from the outlet opening 18 and there the rapidly Form a rotating cone of water.

Fig.4 is the section IV-IV according to Fig.3 and leaves in particular the tangential confluence of the branch line 3 to the nozzles 2 and the initial flow.

2ί device 21 of the supplied water can be recognized.

A particularly complete elimination of the constituents to be removed from the gases can thereby be achieved that the gas to be cleaned in the flow chamber 1 according to F i g. 1 introduced tangentially and thus a rotational movement according to arrow 13 in FIG. 1 in the flow-through chamber 1 executes, this rotational movement favored with a circular cross-section of the flow-through chamber will.

It is particularly advantageous here if the direction of rotation of the entering exhaust gas coincides with the The direction of rotation of the water jets emerging from the nozzles 2 coincides, as this creates a special intimate long-term contact between the exhaust gas and the water is brought about. Independently of However, it is also possible for the exhaust gas to rotate in a direction opposite to that of the To give water jets, creating turbulence in the exhaust gas and the water jets, what for certain elimination conditions can be beneficial.

For this purpose 2 sheets of drawings

Claims (6)

Patent claims: 1. Wet scrubber for separating solid, volatile and gaseous components from exhaust gases, consisting of a flow-through chamber in which the Exhaust gases are brought into contact with the scrubbing liquid by several flat jet nozzles arranged one behind the other in the direction of flow of the exhaust gases create a water curtain filling the cross-section of the passage in the flow-through chamber, the predominantly transverse to the main flow direction of the exhaust gases directed towards the opposite Meet the side of the flow-through chamber, according to Patent 16 71 393, characterized in that that the jet nozzles (2) produce a water cone (14) with an opening angle of at least 90 °, wherein the water cone (14) is directed against the flow direction (13) of the exhaust gases. 2. wet washer according to claim 1, characterized characterized in that the jet nozzles (2) are designed as swirl nozzles, which consist of a hollow body with consistently decreasing 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 one tangential supply line (3) is provided in the area of the largest cross section. 3. wet washer according to claim 2, characterized in that the interior of the swirl nozzle (2) is designed as a closed hemispherical shell, in the point of which it is the greatest distance from the base (19) the outlet opening (18) for the water jets (16) is located. 4. wet washer according to one of the preceding claims, characterized gekennzeici.net that the common Feed line (4) to the jet nozzles (2) in the area of the wall (ladder through-flow chamber (1) is arranged and the jet nozzles (2) over short Branch lines (3) connected to the supply line (4) and in the center of the axis to the throughflow chamber (1) are arranged. 5. Wet washer according to one of the preceding claims, characterized in that the inflow line (11) for the exhaust gases in the flow-through chamber (1) tangential to the cross-section of the flow-through chamber (1) is directed. 6. wet washer according to claim 5, characterized in that the direction of rotation (13) of the Exhaust gases with the direction of rotation (17) of the water jets (16) emerging from the swirl nozzles (2) matches.