DE3709553C2 - Deflecting device for flue gases in cooling towers - Google Patents

Description

The invention relates to a feed device Deflection devices in cooling towers according to the generic term of claim 1. Such a feeding device is for example in Canadian patent application no. 4 92 103, the owner of which is the applicant, and to which the Canadian Patent Office now issued 12 63 301 has been.

Under "cooling towers" there are atmospheric cooling towers for to understand the flue gases cleaned in a damp way, the come from fossil fuel boilers in power plants. To shorten it, the cooling towers with "towers" are and the flue gases referred to as "gases".

The above-mentioned, generic feed device consists of at least one horizontal pipeline that leads the gas into the tower, and that over his heat exchanger body and his Water distribution and its droplet separator, and which have openings at their upper level that are extend almost the entire length of the pipeline and that are surmounted by outlet chambers that emit the gas pick up these openings and horizontally over it Divert droplet separator elements into the tower.

While the gas at the pipeline inlet is a relative has high speed, which is generally 15 to Is 25 m / s, it is proportionate in the tower low speed redirected that between one lower limit and an upper limit must be between which the droplet separators used are effective are. These limit values are included, for example 3 m / s or 6 m / s.

The uniformity of in this way at the outlet of the Deflection device realized gas velocity must over both the length and the height of the Droplet separator elements can be realized.  

In a first embodiment of that in the preceding mentioned Canadian patent application Deflection device is in uniformity Longitudinal direction of the pipeline through the narrowness of the openings sought in the pipeline, making it proportionate high pressure losses when passing through the pipeline located gas occur in the outlet chambers. These relatively simple training has the disadvantage to cause significant energy consumption the pressure losses when passing through the openings to be balanced, on the other hand none To ensure speed range that is so narrow how it would be desirable.

Another embodiment is described in the Canadian patent application in FIGS. 7 and 8. The gap has a relatively large width and the uniformity of the gas velocity in the longitudinal direction at the outlet of the droplet separator plates is achieved by deflecting vanes which are located in the interior of the pipes. While the gas velocity uniformity is very good in this case, the cost of such deflector blades is considerable.

The invention has for its object a even distribution for the flue gas in the To create outlet chambers

• - Their flow rate along the pipeline practically is equal to,
• - The gas outflow at the inlet of the outlet chambers one Gas distribution allowed in the amount of drops separator plates in the side walls of the air boxes are sufficiently uniform, and
• - Which is relatively inexpensive.

This task is solved in that at the Base of the outlet chambers arranged deflection devices are. These deflection devices are perpendicular to Pipeline, which protrude above the outlet chambers, and over arranged the entire length of these outlet chambers. they have a profile that is essentially an arc, and may be designed as an elliptical arch or an oval arch, which extends over an opening angle to the center, and if necessary with a deflection device and the following is designed differently and preferably between 70 and 130 °; the radius of the arc has a value that between 5 and 25% of the width of the deflection device fluctuates. These deflection devices bridge the Opening of the pipeline; their lower edges run either tangent to the profile of the pipeline or cut this, leaving their lowest position there lies where they are the edges of the opening of the pipeline touch, or their lower edges are slightly above the pipeline. The exact location is in generally determined by design reasons. The Deflection devices are attached so that you concave area upstream of the outflow of the pipeline and they are essentially light inclined, from bottom to top, from downstream to upstream, from 0 to 30 °, which may be from a Deflection device can vary to the following.  

The opening has a width that is preferably between 25 and 36% of the diameter of the pipeline lies, this width either in continuous Way (trapezoidal gap) may vary, or in Steps along the pipeline. The high of Deflection devices is relatively large and lies between a quarter and a fifth of the amount of Mist eliminator elements, with their upper level in generally the basis of these droplet separator elements towered over. To avoid the lateral expansion of the gas hinder and no low gas velocity below to have the droplet separator elements are Deflection devices at their ends with arcuate Provide cutouts. These cutouts have a height on the order of 50% of the amount of Diverters and a width that is approximately corresponds to the part of the outlet chambers which none Opening of the pipeline is assigned.

For reasons of economic production Arrangement from the largest possible number of identical Deflection devices, as far as deviations from the uniform speed when passing through the Droplet separators are acceptable. After all, that is Distance between the deflection devices the 1- to 2 times their height.

The invention takes place via the flue gas outflow zones a largely uniform smoke distribution. By this equalization becomes an intimate mixture of Flue gases ensured with the cooling tower swath. By the deflection devices are the flue gas quantities in the Chambers equalized so that the gas largely evenly over the droplet separator elements in the Cooling tower is initiated.

The invention is then based on the drawings explained. Show it:

Fig. 1 shows a longitudinal section through the Auslaßkanmern with deflection devices and droplet above a pipeline,

Fig. 2 shows a cross-section AA of FIG. 1,

Fig. 3 is a plan view of the arrangement of trapezoidal openings,

Fig. 4 is a cross-section, on a larger scale, an embodiment of the mounting of a deflection device over a pipe,

Fig. 5 Fig. 5A is the section AA to Fig. 4. Fig. 5B, 5C and 5D illustrate the holder for the deflection device, in front view, side view and plan view,

Fig. 6 shows the geometric data (dimensions) of a deflection device.

In the different figures denote the same Reference numerals the same components.

As can be seen from the drawings, a horizontal pipeline 1 leads the gases to the tower and, above its heat exchanger body, its water distribution and its droplet separators, is provided at its upper level with an opening 2 which extends over almost its entire length and that of outlet chambers 3 is dominated, which absorb the gases through this opening and deflect them horizontally via the droplet separator elements 4 into the tower.

An arrangement of deflection devices 5 is provided at the base of the air boxes 3 .

The deflection devices 5 run perpendicular to the pipeline, which protrude beyond the outlet chamber. As can be seen from FIGS. 2 and 4, the deflection devices extend practically over the entire width of the outlet chamber and their lower edges 6 extend tangentially to the profile of the pipeline 1 . Figs. 1, 5 and 6 illustrate a circular configuration of the deflecting means is, although they could also be embodied in the form of an elliptical arc or oval arc and extending over an opening angle with respect to the core, α, for example, 120 ° (FIG. 6). The deflection devices 5 are directed with their concave sides upstream of the flow, the flow direction being represented by the arrow X in FIG. 1. The deflection devices are inclined by 10 ° (β, Fig. 6).

Figs. 1, 2 and 4 show the relatively large amount of deflection as compared with the Tropfenabscheiderelementen. It can be seen in particular that its upper level 7 projects beyond the base 8 of these droplet separator elements.

The deflection devices also have arcuate cutouts 9 at their ends. These cutouts 9 have a height of the order of 50% of the height of the deflection devices and their width corresponds approximately to the section of the outlet chambers to which no opening of the pipeline is assigned.

The FIGS. 4 to 5 illustrate an assembly of the deflection. The deflection device 5 is attached to brackets 11 for the droplet separator through elements 12, which are fitted with long holes 13. A holder 14 , which connects the deflection device to the pipeline, is fastened by means of screws and bolts to a band 15 which is arranged on the upper part of the pipeline, the latter being provided with circular, interrupted reinforcements 16 , which are distributed in some places along the pipeline are. Each holder 14 is adjusted relative to the band 15 by means of an elongated hole 17 . The holder 14 is also fastened to the deflection device 5 with the aid of nuts and bolts and is set there by means of an elongated hole 18 .

Fig. 3 shows an embodiment of the opening 2 in a trapezoidal shape, which continuously m varies from 1.22 to 1.45 and m is suitable, for example for a pipe having a diameter of 5.00. This opening consists of cutouts 2 A, 2 B, 2 C, 2 D, 2 E, 2 F.

Claims (12)

1. Supply device with deflection devices in cooling towers, for supplying flue gases which are introduced into the cooling tower through at least one horizontal pipeline, which leads the gases into the cooling tower above the heat exchanger body, the water distribution and the droplet separator, the pipeline at the upper vertex Has openings ( 2 ) which extend almost over their entire length and is surmounted by outlet chambers ( 3 ) which receive the gas through the openings and deflect horizontally via the droplet separator elements ( 4 ) into the cooling tower, characterized by the arrangement of deflection devices ( 5 ), at the base of the outlet chambers. 2. Device according to claim 1, characterized in that the deflection devices ( 5 ) are arranged perpendicular to the pipe ( 1 ) over the entire length of the outlet chambers ( 3 ). 3. Device according to claims 1 and 2, characterized in that the deflecting devices ( 5 ) have a profile which is essentially designed as a circular arc, elliptical arc or oval arc. 4. The device according to claim 3, characterized by arcuate deflection devices ( 5 ) whose opening angle to the center (α) is between 70 and 130 °, the arc radius formed by these deflection devices ( 5 ) having a value which is between 5 and 25% of Width of the deflection devices is. 5. The device according to claim 4, characterized in that the opening angle (α) differs from one Deflection device changes to the next. 6. Device according to claims 1 to 5, characterized by deflection devices ( 5 ), the lower edges ( 6 ) of which extend tangentially to the apex of the pipeline. 7. Device according to one of claims 1 to 5, characterized by deflection devices ( 5 ) whose lower edges ( 6 ) cut the profile of the pipeline. 8. Device according to one of claims 1 to 7, characterized by deflection devices ( 5 ) which are slightly inclined from bottom to top and from downstream to upstream by 0 to 30 ° (angle β, Fig. 6). 9. The device according to claim 8, characterized by Deflection devices, the inclination (β) of which Deflection device changes to the next. 10. Device according to claims 1 to 9, characterized by a pipe, the gap opening ( 2 ) has a width which is between 25 and 36% of the diameter of the pipe ( 1 ). 11. Device according to claims 1 to 10, characterized in that the deflection devices ( 5 ) are provided at their ends with cutouts ( 9 ). 12. The apparatus according to claim 11, characterized in that the cutouts ( 9 ) have a height in the order of 50% of the height of the deflection devices, and a width which approximately corresponds to the section of the outlet chamber ( 3 ), which no opening of the pipeline assigned.