FR2739306A1 - SPRAYER FOR CHARGED LIQUIDS, IN PARTICULAR ABRASIVE NATURE - Google Patents

Abstract

Spraying device for solid-laden liquids, particularly of the abrasive type, wherein the liquid to be sprayed, introduced tangentially into an annular groove (1) from which it overflows on one side only in order to form a hollow cone of fine droplets, comes in contact, when overflowing, with a circular cross-section movable member (2) held loose about an axis (3) along which it may be displaced rotationally and translationally in a limited way, said liquid causing the rotation of the movable member, characterized in that, when inactivated, the movable member (2) is in contact with the central portion (6) of the annular groove (1) so as to leave free a substantially annular passage for the liquid between the overflow surfaces (10 and 8) and the periphery of said member (2), and in that, due to the clearance of that member (2) rotationally actuated by the liquid, the contact between the liquid and said member causes a spraying effect and the generation of very fine droplets.

Description

FIELD OF THE PATENT
The present invention relates to a sprayer specially adapted for liquids containing a suspension of solid particles that can be abrasive.

STATE OF THE ART
Liquid spraying is an important problem for many industrial applications. Among these we can mention: hot gas cooling, gas conditioning, flue gas cleaning ... It is known that a particularly effective method for spraying liquids in the form of very fine droplets consists of simultaneous injection pressurized gas and spray liquid. However, this solution does not lend itself to the use of liquids loaded solids, the risk of clogging being significant.

 It is also known that an effective method in the case of heavy particles loaded liquids is to inject the liquid tangentially into an annular groove inside which it rotates at high speed and from which it flows tangentially in the form of one or more layers. French Patent No. 2,304,409 describes such a device. However, a very fine spray is not obtained in this case, the speed of the liquid can not be very high in the presence of abrasive liquid.

SUMMARY DESCRIPTION OF THE INVENTION
The present invention aims to remedy these disadvantages.

 For this purpose, in a sprayer in which the liquid is fed tangentially into the inner part of a shallow groove inside which it is rotated and overflows from this groove on one side, there is provided a movable member circular section loosely held around a fixed axis to come into contact with the liquid overflowing the groove and thereby promote the formation of fine droplets.

DETAILED DESCRIPTION OF THE INVENTION
Figure 1 is a cross section (following II of Figure 2) of the spray object of the invention.

FIG. 2 is a view from above with partial section (following
II-II of Figure 1).

 Figures 3 and 4 illustrate the tests carried out with a sprayer according to the invention.

 In Figure 1, the sprayer shown comprises a hollow annular body open on one of its faces. The edge (8) of the opening has a tapered profile flared towards the outside. The interior space is hollowed out with a groove (1) with a spiral-shaped transverse profile, its depth thus decreasing from the point of supply of the liquid to a deflector (7), ie after a slightly lower angle to 3600. This groove (1) is connected to the conical edge (8) by a substantially ring-shaped curved surface (10) of inner diameter Di. The deepest part of this groove (1) is connected to a feed chamber (9) provided with a connecting flange (12).

 The other sprayer face is closed by a flat surface (6) which is preferably raised above the mean plane of the groove (1). On this planar face (6) is welded an axis (3) on which is fixed, for example by a system of nut and locknut (5), a large disc-shaped washer (4) whose center coincides with the axis of the conical edge (8) and whose surface is parallel to the plane of the face (6), its diameter being slightly smaller than the diameter Di. Between this washer (4) and the face (6) is mounted a movable member of revolution (2), hollowed by a cylindrical inner recess of diameter much greater than that of the axis (3), preferably at least 1, 7 times this diameter. The outer surface of revolution is preferably conical by being more flared on the side of the washer (4). Advantageously, this movable member (2) has a small height relative to its average diameter, preferably less than 1.9 times that diameter.

 The operation is as follows: the liquid coming under pressure from the chamber (9) is introduced tangentially into the groove (1) at the point where it is the deepest and is rotated therein. As the liquid advances angularly, the depth of the groove decreases, so that the liquid is gradually and uniformly ejected towards the curved surface (10) where it comes into contact with the movable member (2), which which has the effect of breaking its cohesion and thus generating a set of fine droplets ready to be ejected. The liquid thus divided escapes through the very open cone-shaped edge (8) directed outwards by defining a hollow cone with very small droplets of said liquid. The movable member (2) is set in motion. rotation around its axis by the kinetic energy provided by the liquid.

 The function of the deflector (7) is not only to complete the ejection, but especially to force the removal of any solid particles that may have a tendency to accumulate at the bottom of the groove in the absence of said deflector. Since the sprayer does not have a very narrowed part, we are in a situation where we are, by design, safe from clogging.

 The deflector (7) has in its preferred embodiment, a triangular profile. The movable member (2) advantageously has a taper angle of 5 to 15 degrees and it touches the liquid projecting from the groove (1) in the portion of the curved surface where the speed of this liquid is very high.

 To demonstrate the advantages of the sprayer according to the invention, two series of experiments were carried out. The scheme of experiments is described in Figure 3 where we can see the sprayer (b) mounted in the center of a tank (g) whose diameter is 4 m. The water (e) is circulated using a pump (c) which feeds the spray (b), which projects a veil of droplets (a). The temperature of the water is measured in several points including (d). The performances were compared with those of a "conventional" sprayer, obtained by operating the sprayer according to the invention without its mobile member (2).

 The first experiment aimed at establishing, all other things being equal, that the droplet size distribution is finer.

To do this, the liquid flow rate, which reaches a distance d defined with the aid of a container (f) cut from a slot of dimensions w = 20 mm per h = 150 mm, has been measured, which container is moved in a movement of revolution around the sprayer (b). The water used for these experiments was fed at a pressure of 331 kPa. The main data are summarized in the table below.

<tb> Type <SEP> of <SEP> Flow <SEP> measured <SEP> Flow <SEP> collected <SEP> Flow <SEP> collected <SEP> Flow <SEP> collected
<tb> pulvè <SEP> to <SEP> the <SEP> pump <SEP> to <SEP> d <SEP> = <SEP> 500mm <SEP> to <SEP> d <SEP> = <SEP> 1400mm <SEP> to <SEP> d <SEP> = <SEP> 2000mm
<tb> riser
<tb> Without
<tb> organ
<tb> mobile <SEP> 6m3 / h <SEP> 6m3 / h <SEP> -nd- <SEP> 4m3 / h
<tb> organ <SEP>
<tb> mobile <SEP> 5m / h <SEP> 5M / h <SEP> 3m h <SEP> 0.6m / h
<Tb>
It was verified that the height of the slit used for the measurement was sufficient to intercept the entire veil. The decrease in the amount of water reaching the wall is explained by the fact that much finer drops are generated by the following sprayer. the invention and that these fine drops, comparatively more aerodynamically braked than the big ones, can not reach the wall and are evaporated en route. This phenomenon of increased evaporation has been found in subsequent tests.

In a second series of tests carried out to evaluate the mass transfer performance, the temperature profile and the total amount of water evaporated at the end of the tests obtained by spraying hot water in a chamber were measured. containing air as shown in Figure 3. The water temperature is approximately 40 degrees for each test.The main results are given in the following table:

<tb> day <SEP> of <SEP> test <SEP> Type <SEP> of <SEP> sprayed - SEP> Duration <SEP> of <SEP> test <SEP> quantity
<tb><SEP> evaporator <SEP> evaporated
<tb><SEP> day <SEP> 1 <SEP> with <SEP> organ <SEP> Im <SEP><SEP> 3
<tb><SEP> mobile <SEP> 12 <SEP> mm <SEP> 0.10 <SEP> m
<tb><SEP> day <SEP> 1 <SEP> without <SEP> organ
<tb><SEP> mobile <SEP> 12 <SEP> mm <SEP> 0.03 <SEP> m
<tb><SEP> day <SEP> 2 <SEP> with <SEP> organ <SEP><SEP> 3 <SEP>
<tb> day <SEP> 2 <SEP> mobile <SEP> 30 <SEP> mm <SEP> 0.08 <SEP> m3
<tb><SEP> day <SEP> 2 <SEP> without <SEP> organ <SEP> 30 <SEP> mm <SEP> 0.04 <SEP> m
<tb><SEP> mobile
<Tb>
For each of the tests, it can thus be seen that the amount of water evaporated is at least two to three times greater with the invention described. In absolute terms, the differences observed from one test to another (day 1 vs day 2) are due to variations in the humidity conditions of the air. FIG. 4 shows the evolution curve of the temperature as a function of time for the two configurations (curve (a) without moving member and curve (b) with moving member). The faster temperature decrease obtained with the invention, the final temperature level as well as the above observations clearly establish the superiority of the sprayer according to the invention.

Claims (4)

R E V E N D I C A T IO N S  A sprayer for charged liquids, in particular of an abrasive nature, in which the liquid is introduced tangentially into an annular groove (10) from which it overflows on one side to form a hollow cone of fine droplets, characterized in that a movable member (2) with a circular section loosely held around an axis (3) comes into contact with the overflowing liquid.  2. Sprayer according to claim 1, characterized in that the height of the movable member (2) is reduced relative to its diame- ter.  3. Sprayer according to any one of claims 1 and 2, characterized in that the movable member (2) has a tapered outer profile reduced angle.  4. Sprayer according to any one of claims 1, 2 or 3, characterized in that the movable member (2) has a diameter at least 1.7 times equal to the diameter of the axis (3) around which it is mounted.