DE1719485C3 - Device for separating a liquid and / or vaporous medium from a carrier gas - Google Patents

Description

The invention relates to a device for separating a liquid and / or vaporous medium from a carrier gas with a spiral element arranged in a tube and designed as a screw, especially for use in aircraft.

In air conditioning systems it is often necessary to to free the cooled air of condensed moisture, the water separation in more advantageous Way is carried out immediately after the air cooling. The water separation devices provided for this purpose are therefore usually as naughty as possible in the air conditioning system! ; the refrigerator arranged.

In a device of the type described above known from US Pat. No. 2,751,037, this is Twist organ a snail with a constant pitch. However, due to this constant slope, the known device at the inlet end of the screw undesirably a considerable pressure loss on that, because of the increase with the square of the flow velocity, especially at high Flow velocities in the air conditioning system is unfavorable.

It is the object of the present invention. in a device of the type described above To minimize pressure losses.

According to the invention, this object is achieved in that the screw is continuous in the direction of flow has decreasing slope. Such a device can therefore also be used at high flow velocities, z. B. in the order of 50 m / sec, and in air conditioning systems in aircraft be used where the device should be as small and light as possible and where With regard to a minimal power dimensioning, the lowest possible pressure drop should occur. Accordingly, the device according to the invention also has a high efficiency in the deposition liquid and / or vaporous media from carrier gases, what is inbesöridere in dehumidifying in air conditioning systems in aircraft from The advantage is that there is steam precipitation on navigation ^ and other monitoring tools Impair flight safety,

Provide advantageous hamlet formations of the invention

from the subclaims.

The invention is explained in more detail below with reference to the drawing. It shows
F i g. 1 a view of a separation device,
2 shows a longitudinal section of the device according to FIG. 1,

3 shows an enlarged side view of the screw the device of FIG. 2 and

F i g. 4 and 5 show a longitudinal section and a rear view another embodiment of a separation device.

According to FIG. 1, the separation device has the

outer shape of a cylindrical tube 1, which has an open end 2 for the inflow of the steam-containing, cooled gas, e.g. air in the direction of the arrow shown and an open end 9 for outflow of the dehumidified gas or the dehumidified air in the direction of the arrow cuff-like extension 14, in far the separated water is collected and to which a pipe 15 is connected to drain the collected water. The pipe 1 is connected to the end 2 connected to the outlet opening of a gas or air cooling device, not shown. The output side End 9 is connected to one or more other pipelines, not shown, through which the cooled air, which has largely been freed from water, is directed to the desired outflow locations. This in F i g. 1 shown, tubular water separation device therefore represents part of the cooling device to The place of consumption is the routed air line. Since in most cases the cooling device is set up directly at the place where the conditioned air is needed, is not wanted or is not possible, a Connection line can be provided anyway. The illustrated water separator replaces this connecting line partially or completely, so that it does not take up any additional space in an advantageous manner.

Further details of the in F ^.; G. The device illustrated by way of example will be described in the following with reference to FIGS. 2 and 3. At the open end 2 of the pipe 1. through which the steam-containing, cooled air flows, a straight pipe section 3 connects, in which the generation of condensate from steam is effected. This is followed by a pipe section 4, which can have a slight curvature and which is provided as a flow path for the water droplet-air mixture if the pipe 1 is not laid in a straight line over its entire length for reasons of space

5C · can. The pipe section 4 can, however, also be omitted. The length of section 4 and its Curvatures are therefore completely irrelevant with regard to the function of the device.

The pipe section 4, which may be present, can be separated from the pipe by means of couplings section 3 and the pipe section 5 be connected, so that the / ur actual device belonging sections 3 on the one hand and 5 to 8 on the other hand can form completely separate units. Even if there is no pipe section 4. can you· Pipe sections 3 and 5 can be separated from one another by a coupling,

Then a straight pipe section 5 is provided in which the axially flowing mixture

& ■> one that is continuously accelerating downstream Rotation around the flow axis is superimposed, so that the heavy water droplets in a subsequent, straight, intended as a hiking corner

Pipe section 6 due to their greater centrifugal force push against the wall of the pipe 1, while the lighter air is displaced inwards into the area around the pipe axis. This hiking route represents an essential functional element of the device. Seme optimal length is in the range from 1 to 2 times the inner diameter of this pipe part. In the subsequent pipe section 7, the cut off Water droplets for the most part excreted and removed through line 15.

Another straight pipe section 8 is used to make the component that is still present rotate more rapidly to continuously eliminate the air flowing on again, so that at the outlet end 9 of the Tube 1 only has an at least approximately axial air flow. Can have the same effect can be achieved in that instead of the pipe section 8 an evolute 18 is provided, the air is led away tangentially and perpendicularly to the preceding pipe section, as shown in FIGS. 4 and 5 can be seen.

In the pipe section 3 is a fine mesh Network of thin metal wires and supporting sheet metal ribs existing component 10 is arranged. This one has the Task, as large as possible of the steam present in the incoming, cooled air to be eliminated. The sudden pressure change associated with the passage of the gas through the network and the resulting in a decrease in temperature improve the preconditions for such a decrease Excretion, so that the metal molecules released by the mesh made of the appropriate metal cause the formation of water droplets as condensation nuclei with a catalytic effect. It is so z. B. possible to use a network made of stainless steel as a so-called condensing grid and this optionally to be combined with a further catalyst, /. B. with silver iodide. This has an advantage Component 10 has the shape of the surface of a cone, the axis of which lies in the flow axis and the Point is directed against the current. The base of the cone corresponds roughly to this Cross section of the pipe 1. The component 10 can be made by a self-supporting mesh and / or by sheet metal ribs be formed supported, which is pushed into the tube 1 and at the desired S'elle, for example is secured against displacement by stops such as rivet pins.

The swirl element which is arranged in the pipe section 5 and which generates the rotation of the air flow consists of a fixed, one-piece and consisting of a single workpiece screw 11. The Both surfaces of the screw 11 together with the cylindrical wall of the tube 1 form two screws shaped channels through which the air flows and which accordingly give the air flow the desired Convey twist.

The screw 11 is shaped so that its pitch in Direction of flow progressively and continuously from an infinitely large value to a very small one Value decreases. This causes the air flow successively deflected so that pressure losses due to the flow breaking off at the leading edge 11 ' be avoided.

In Fig.3 is an embodiment of the in Fig.2 schematically shown screw 11 shown in an enlarged side view. The screw 11 has a half aisle and is profiled on its leading edge 11 'and / or on its trailing edge. she can For example, milled from solid material using a program-controlled milling machine or through Twisting a sheet metal strip in a jig, which the desired progressive pitch causes to be produced. The screw 11, which is overturned to the inside diameter of the pipe 1 (FIG. 2) is inserted into the pipe 1 and at the intended location (pipe section 5), for example

ίο by means of rivet pins inserted into the tube Moving and twisting secured.

In the pipe section 7, slits 13 are arranged in the wall of the pipe 1 which run obliquely, approximately transversely to the resulting flow direction prevailing on the wall and overlap in the flow direction. In addition, the pipe section 7 is surrounded by an outer jacket 14, the inner wall of which delimits an annular space with the outer wall of the pipe 1. The water droplets running along the inner wall of the pipe 1 from the pipe section 6 · & η pass through. ; e slots 13 outwards and are through the mante. ' 14 collected, whereupon they step outside through the downward line 15. The line 15 has a constriction 16. which represents a throttle for the air entering the jacket 14 with the water droplets or the slots 13 and thereby keeps the loss of air low. The jacket is advantageously eccentric with respect to the gas pipe.

In the last pipe section 8, a component is arranged that the rotation of the air flow again eliminated and which also consists of a fixed screw 12, which, however, to the first screw 11 is arranged in the opposite direction and its slope progressively increases from a very small value increases a very large value. The screw 12 is advantageously a mirror image of that in FIG. 3 shown screw 11 and otherwise exactly the same trained like this.

The straight pipe section 8 and the screw 12 arranged therein can also be replaced by a Evolute 18. As shown in Figs. 4 and 5 is shown. The Evolute 18 is an eccentrically arranged collecting chamber, which eliminates the rotation of the air flowing further by keeping the air in a bulge collected from increasing cross-section and after almost one revolution finally tangential to the pipe, perpendicular to the original flow axis, wegge leads.

With the addition of the new speed component due to the generation of the rotation in section 5, there is a drop in the static pressure in c'er Flow connected. When the rotation is eliminated in section 8 or in evolute 18, this becomes Pressure drop recovered for the most part, bringing that in the entire device between the Inlet 2 and outlet 9 measurable pressure loss is significantly reduced.

The entry, end 2 and the exit end

ho end 9 of tube 1 have the same diameter like the preceding or following lines of the air conditioning system. The pipe tube 3, 4,5,6,7 and 8 are of the same diameter or only insignificantly larger than the lines mentioned. the

fi) length of the device from end 2 to 9 without the Section 4, but with section 8, about 10 times larger than the pipe diameter. As already mentioned, the pipe section 4 can be straight or curved

and be of any length. These properties of the device, together with the fact that in most cases one between the cooling unit and the room to be provided with conditioned air certain line length is necessary anyway that the additional space requirement on the additional space requirement in the pipe section 7, d. H. on the space requirements for the jacket 14 and the line 15 and possibly for the evolute 18 remains limited. Since the wall of the Pipe sections 3, 4, 5, 6, 7 and 8 of the normally corresponds to the existing pipeline wall, the additional weight of the device compared to a simple line consists only of the weight of the reticulated and supported component 10, the two screws 11 and 12, the shell 14 and the

Drain line 15, which represents only an insignificant increase in weight. Finally, the described Device has the advantage that the separation efficiency is relatively high, i. H. for example 60%, and that the funds provided for this purpose are produced easily and without particularly high costs can be, and that the device is also practically maintenance-free because there are no moving parts and non-metallic material is present.

Thus, the cooled air in the cooling device, which is connected upstream of the device, not to strengthening ej again in the field of device ^r wäfifieh, kanfi, it is expedient to wrap with einer'.isolierschicht 17, the pipe 1 (Fig. 2) ^

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Device for separating a liquid and / or vaporous medium from a Carrier gas with a swirl element arranged in a tube and designed as a screw, thereby characterized in that the screw (11) has an in Has flow direction continuously decreasing slope 2. Device according to claim 1, characterized in that that the pitch of the screw (11) in the direction of flow from towards infinity to one very small value decreases 3. Apparatus according to claim 1 or 2, characterized in that the screw (11) in the flow direction an evolute (18) or a second screw (12), the pitch of which in the direction of flow rises continuously from a very small value to a very large value, is connected downstream.