DE1136166B - Flow channel for liquid or gaseous media opening into an outflow opening - Google Patents

Description

In the case of channels through which a liquid or gaseous medium flows and which are in a diverging End part, the solid wall of this diverging part causes a reduction in speed of the medium flow with an increase in the static pressure, and this reduction in speed under pressure increase is accompanied by a loss of energy, which affects the harmful Effect of the boundary layers of the medium flow is due.

The purpose of the invention is to provide a discharge opening which ends in a diverging part and which leads into an outflow opening opening flow channel for liquid or gaseous media with an outflow opening of the The blow-out nozzle immediately surrounding the flow channel and fed by a pressurized auxiliary medium to create in which this energy loss is very small, because with him the harmful effect the boundary layers of the medium flow in the diverging part of the flow channel to a minimum is reduced.

According to the invention, the blow-out nozzle points in one of the direction of the out of the flow channel exiting main flow diverging direction, so that the auxiliary medium after leaving the exhaust nozzle in extension of the solid wall of the Flow channel forms a diverging medium wall surrounding the main flow.

There are known water jet suction devices in which the propulsion jet emerges from an annular nozzle and forms a wall surrounding the medium to be conveyed. A diffuser effect occurs in these arrangements but not one, since the propulsion jet nozzles are not directed diverging to the axis of the ram jet are.

It is also known, in the case of channels through which a medium flows, in which cross-sectional or Changes in direction occur to arrange a body of revolution at the point of change, which on circulates its part delimiting the channel in the direction of the flowing medium. This is true also causes a reduction in flow losses. However, these arrangements are under construction and complicated in operation and cannot be used with spatially expanded diffusers.

The invention is explained in more detail below with reference to the drawing of some exemplary embodiments explained.

1 is a schematic longitudinal section through a flow channel designed according to the invention which forms a venturi or ejector tube;

2 is a schematic longitudinal section through opening into an outflow opening

Flow channel for liquid

or gaseous media

Applicant:
Societe Bertin & Cie., Paris

Representative: Dr. E. Wiegand, Munich 15,

and Dipl.-Ing. W. Niemann,
Hamburg 1, Ballindamm 26, patent attorneys

Claimed priority:

France of November 29, 1955 and June 25, 1956
(No. 703 570 and No. 57 353)

Jean Henri Bertin, Neuilly-sur-Seine, Seine,
and Francois Gilbert Paris, Garches, Seine-et-Oise

(France),
have been named as inventors

a further embodiment of the invention which forms the air inlet of a jet engine;

3 is a schematic longitudinal section through a flow channel designed according to the invention, which is a connection between two pipeline sections different cross-sectional areas forms;

Fig. 4 shows a schematic longitudinal section of a further embodiment of a flow channel according to the invention;

Fig. 5 is a schematic longitudinal section and
6 shows an end view of a further embodiment of the invention applied to an ejector.

In the embodiment shown in Fig. 1, a converging flow channel 1 is provided with a fixed wall, which is rotationally symmetrical to the axis aa . At the narrowest point, this converging channel 1 merges into an outflow opening 2 which is directly surrounded by an annular blow-out nozzle 3. This blow-out nozzle 3 is fed with a pressurized auxiliary medium from a conduit 5 via a collecting space 4. When exiting the blow-out nozzle 5, the auxiliary medium generates a veil-like jet 6.

209 639- / 202

3 4

The blow-out nozzle 3 is directed outwards in such a way. The examples according to FIGS. 1 and 2 show the

that the velocity vector V of the auxiliary medium different shapes in which the medium wall

can bend at the outlet of the nozzle with the axis aa of the main depending on the pressures,

Stromes forms an angle α, so that the exiting which prevail on their inside and outside.

Medium jet 6 a diverging medium wall in 5 In Fig. 1 it is assumed that on the outer

Extension of the fixed wall of the flow channel 1 side of the medium wall 6 of the atmospheric pressure p _a

forms and the main stream exiting from this prevails, while the pressure on its inside of

surrounds. a negative pressure prevailing at the narrowest point

The medium wall 6, which at its beginning in the downstream direction gradually up to the

Direction of a cone jacket with a cone angle ίο value p ₀ increases. The medium wall 6 therefore takes

runs from 2 α, causes an outwardly convex curvature like a fixed diverging one.

Wall there is a delay that occurs at the narrowest point. In the case shown in FIG

sufficient speed of the main stream, but on the other hand in the stream a steadily increasing excess

with low flow losses, namely by pressure, while the external pressure is at the value p ₀

that the boundary layers remain at a slower rate. The medium wall 6 therefore has an after

as in flow channels with a fixed, externally concave curvature.

diverging wall are observed, avoided. The embodiment according to FIG. 3 relates to or are reduced. The pressure of the auxiliary medium feeding the blow-out transition from a pipe 10 with a small transverse nozzle 3 can be selected in such a way that the section to a pipe 11 with a larger transverse section is such that the initial speed V der from FIG. The solid walls of the two pipes Ausblasdüse 3 exiting stream filaments at least are arranged overlapping each other, and the comparison of the velocity of the main flow at the connection between them is made by a diverging point, ie at the outflow opening 2 of the generating medium wall 6, which is made by a channel 1 is. an annular blow-out nozzle 3 exiting auxiliary s-The arrangement described above acts 25 medium is formed. The medium wall 6 replaces even without an additional propulsion jet as a jet here a divergent fixed transition wall, pump, in which the entrainment of the main medium entering the convergent channel 1 offers the advantage here too, by the friction of the high speed that it causes the conversion of the velocities and flowing auxiliary medium on the molecules of the 30 pressures with a minimum of losses. Medium wall 6 touching main flow takes place. In the embodiment shown in FIG. 4, however, in order to increase the propulsive effect on the main mold downstream of a medium of a solid wall, an additional axial propellant converging flow channel 41, whose jet, which emerges from a nozzle 7, can be used. be provided. Outflow opening from a collecting space The media, both that which forms the divergent medium wall 6 surrounding the divergent, ring-shaped blow-out nozzle 43, and that which is a divergent and fairly short of the main flow can, depending on the collection line 45 into the eye, with arranged fixed wall, the combined use gases or liquid with the converging channel 41 through webs 46, keiten. The arrangement can also be operated 46 'connected. The collecting line 45 has an inlet piece 47 that is rounded off by a liquid at 4 °. An auxiliary medium exiting from a gas blow nozzle43 and the main flow is generated in a flow-like manner or vice versa. downstream of the outflow opening of the channel 41 a In the model shown in FIG. 2, exemplary diverging medium wall of which is indicated by the wedges F-F, for example, it is the air inlet '.

Jet engine, which moves at great speed. In this example it is assumed that the flow emotional. Such engines require a diffusion of the main medium in the converging one fusor, which serves to remove the air that has entered. Flow channel 41 by the propellant effect of the slow and their kinetic energy in the pressure of the exhaust nozzle 43 exiting auxiliary medium energy to convert. According to the invention is included. The collection line 45 is supposed to diverging solid wall of such a diffuser 50 lead the main medium and the auxiliary medium, if replaced by a medium wall 6, which from one of the auxiliary medium on a certain effective distance the an annular blow-out nozzle 3 exiting HiUs most of its energy and thus its active medium jet is formed. The blow-out nozzle 3 has lost its solitude. The collecting line 45 finds over at the rear edge of a flow channel then takes on the task of the medium wall and in the form of a hollow ring 8, which brings in the air 55, the main medium with low losses of the engine. The cavity of the atmospheric pressure. The collection line 45 of the annular flow channel 8 is about a must adapt to the medium wall, and since the Feed pipe 5 with pressurized gas, the latter has a strong divergence (with a half feeds, for example with the compressor of the drive cone angle of z. B. 30 °), the diameter must plant removed or from a special 60 of the collecting line 45 at its narrowest point essential auxiliary compressor supplied air. After the borrowed (e.g. by 20 to 50%) be greater than the borrowed Channel 8 entered main air flow in that of the knife at the narrowest point 42 of the convergent the medium wall 6 surrounds a diffuser a flow channel 41.

has experienced slowing down and compression, he arrives. The ejector according to FIGS. 5 and 6 has a into a collecting line 9, which leads it to the drive 65 flow channel of rectangular cross-section, work leads. The entrance of the collecting line 9 is that of two flat walls 21 and two convertible shaped so that it is delimited by the divergent medium-gent walls 22. On the edge, but on the inside 6 envelops. half of the outflow opening of this flow channel,

through which the air flow passes are two straight ones running at right angles to the walls 21 Blow-out nozzles 23 are arranged, which are supplied with a pressurized auxiliary medium from feed lines 27 are fed via collecting spaces 26 and produce two diverging medium walls 24 between the two flat solid walls 21 of the flow channel. The blow-out nozzles 23 follow the convergent solid walls 22 of the flow channel offset inside, so that passages 25 are present through which air flows through the friction is sucked on the outside of the medium walls 24. In this way the driving effect becomes the medium walls increased on the main air flow, so that on a special central propulsion jet can be dispensed with.

The last-mentioned embodiment can also be designed to be rotationally symmetrical, with an Instead of the two straight blow-out nozzles 23, an annular blow-out nozzle would have to be used.

The auxiliary medium used to generate the medium walls can be a liquid, e.g. B. water or mercury, which can be recovered.

The effectiveness of the medium curtain is proportional its size of movement, and when using a liquid it is easy to get a very large size of movement to achieve. Furthermore, the medium wall formed by a liquid is more homogeneous than a gaseous one, and it is less rapidly destroyed by contact with the atmosphere.

By changing the pressure of the auxiliary medium, the density of this medium and the size and The device can be adapted to the respective operating conditions in the direction of the blow-out nozzle.

Furthermore, it can be useful to discharge the auxiliary medium from the blow-off nozzles with respect to To modulate pressure and quantity or to make it pulsating. This results in the known advantages a pulsating propulsion jet, such as the generation of eddies and the increase in efficiency.

The modulation or pulsation of the auxiliary medium delivery can be carried out by known means, e.g. B. by intermittent Incineration or by periodic shut-off.

Claims (6)

PATENT CLAIMS:
1. In an outlet opening flow channel for liquid or gaseous media with a discharge opening of the flow channel immediately surrounding, fed by a pressurized auxiliary medium, characterized in that the discharge nozzle (3, 23, 43) in one of the direction of the the main flow exiting the flow channel (1, 8, 10, 26, 41) points in a divergent direction (F), so that the auxiliary medium, after leaving the blow-out nozzle, extends a diverging medium wall (6, 24, F- surrounding the main flow as an extension of the fixed wall of the flow channel) F ') forms. 2. Flow channel according to claim 1, characterized in that the fixed wall of the flow channel (1, 41) converges in front of the discharge opening, so that it coincides with the diverging Medium wall (6, F-F ') forms a Venturi nozzle. 3. Flow channel according to claim 1 or 2, characterized in that downstream of the outflow opening of the flow channel (8, 41) a collecting line (9, 45) is arranged with a fixed wall, which the diverging medium wall generated by the annular exhaust nozzle (3, 43) (6, F-F ') and absorbs the flow emerging from the flow channel (8, 41) (FIGS. 2 and A). 4. Flow channel according to claim 3, characterized in that the solid wall of the collecting line (45) extends divergent in extension of the diverging medium wall {F-F ') generated by the annular blow-out nozzle (43) and is provided with a convergent inlet piece (47) (Fig. 4). 5. Flow channel according to one of claims 1 to 4, characterized in that the blow-out nozzle (23) to increase the ejector effect of the diverging medium wall (24) at the edge, but is arranged within the main flow passing through the outflow opening (Fig. 5, 6). 6. Flow channel according to one of claims 1 to 5, characterized in that the auxiliary medium a liquid, e.g. B. water or mercury. Considered publications:
German Patent Nos. 407 202, 583 792, 286; French Patent No. 1 006 146;
Lexikon der Physik, 1950, Vol. I, p. 449. 1 sheet of drawings © 209 639/202 8.