DE10163896A1 - Wind tunnel jet has a boundary layer separation device that prevents flow separation and enables stable flow to be achieved with a smaller flow development length - Google Patents

Abstract

Device for flow-separation free guidance of a fluid flow within a jet (5) arranged in the flow comprises a device for separating the boundary layer region (11) of the flow from the main flow (3) prior to its entrance into the jet. An Independent claim is included for a method for improvement of the flow quality in and after a jet of a flow device.

Description

The invention relates to a device and a method for the free transfer of a flow in a in the Flow arranged nozzle.

A flow guide with a defined flow quality is especially in the determination of aerodynamic Properties of bodies and profiles as well as for calibration aerodynamic measuring instruments required.

Nozzles are used in particular in wind tunnels with closed Return (Göttinger type) to, given Air velocity in the measuring section one possible low air velocity in the rest of the air duct too as this results in lower friction losses. Only shortly before the measuring section, the flow through the Nozzle accelerated by reducing the flow area becomes.

Another advantage of a nozzle is that through the contraction of the flow the turbulence and the Distribution of speed over the cross section is improved. Therefore you will find nozzles in wind tunnels with open air duct (Eiffel type).

In the margins of currents occur special aerodynamic phenomena. Formed on solid walls Friction, resulting in a laminar or turbulent Boundary layer in the flow leads. At free Flow margins, z. B. between dormant and flowing Air, creates a shear layer.

Boundary layers on walls tend to increase when the pressure rises Detachment, with turbulent boundary layers opposite laminar boundary layers only at a larger one Replace pressure increase. Also, the thickness of the trained Boundary layer in the problem of flow separation of Meaning.

The contour of a nozzle should be designed so that through a slow, continuous decrease in the Nozzle cross section local pressure increases and one with it increased risk of flow separation can be avoided. Of the static pressure in front of the nozzle should be possible in the nozzle low loss can be converted into kinetic energy. Is to in general, depending on the contraction ratio and the desired flow quality, a certain length of the Nozzle necessary. There are calculation methods with which predetermined velocity distribution at the nozzle exit the Contour for a minimum nozzle length can be calculated. Often, however, is due to a sufficient length given conditions not available, or it is already given a nozzle with insufficient contour.

The problem underlying the invention is the nozzle so form and arrange that the flow as possible guided through the nozzle without detachment and for the nozzle necessary length can be kept as small as possible.

To solve this problem is in a generic Device proposed that in the inlet region of the nozzle a device for separating the edge region of the flow is arranged.

The already low energy in the inlet region of the nozzle Boundary layer, with the correspondingly high risk of Replacement is already in the inlet area of the nozzle led away. This makes it possible, at the inlet of the nozzle a Wall boundary layer to emerge new, the less to Detachment tends as the boundary layer of one at the nozzle entrance incoming flow. Nozzle contours with greater inclination and shorter length can be realized in this way, without the risk of flow separation increases ..

Advantageously, the nozzle is preceded by an antechamber and the device is a Teilstromausleitung. With the Antechamber, the flow is defined led to the nozzle and by means of Teilstromausleitung can also separated volume fraction defined to be dissipated. This For example, it is important to have a backwater To be separated flow in the remaining part Volume flow to avoid.

It is particularly advantageous if the Teilstromausleitung a fully between the Outside of the nozzle and the wall of the prechamber trained Gap is through which the part of the flow to be separated discharged without further mechanical guide devices can be, being in a geometrically particularly favorable Execution of the gap is annular. The Flow area of the nozzle border is to be designed in this way that at this, if at all, only small Turbulence and as possible no backwater forms.

Further, it is convenient to the wall of the antechamber on the Continuing to the inlet opening of the nozzle, since this enables a largely low-loss Teilstromausleitung. The discharged air volume can then without further air flow or further active measures in the measuring section enter surrounding plenary.

In an alternative embodiment, the nozzle in the Entry area openwork wall sections, through the the edge region of the flow can be separated. there it is particularly favorable, the passage of the Edge regions of the flow through the nozzle wall by means of a on the outside of the nozzle arranged suction fan support. In particular, this is a turbulence generating backflow in the nozzle avoidable.

The above object is achieved by a Method for improving the flow quality in and after a nozzle of a flow device, in particular a Wind tunnel, loosened by the edge areas of the incoming Flow in the inlet opening of the nozzle from the nozzle flow be separated and thus the separation and turbulence-prone layer of the flow does not pass through the nozzle is guided.

Further advantages and features of the invention, the following description of the in the drawing illustrated embodiments and the individual Claims are taken.

In the drawing shows:

Fig. 1 shows a detail of a schematic wind tunnel in longitudinal section

Fig. 2 is a wind tunnel analogous to FIG. 1 with an alternative nozzle training

The wind tunnel shown in FIG. 1 1 is flowed through by a medium 2 in the direction of flow 3 and has a measuring section 4, can be carried out in the aerodynamic on a not-shown body, a profile or a measurement probe studies.

For these investigations, it is generally very important to achieve calculable, that is as uniform as possible, flows with constant velocity and pressure vectors in the area of the measuring section 4 above the cross section of the flow.

For the purpose of a uniform flow of the medium 2 in the measurement path, the flow in one of the measuring path upstream nozzle 5 with an inlet opening 5 a, 5 b of a nozzle wall and an outlet opening 5 is compressed and accelerated c. The medium 2 is guided by means of a closed pre-chamber 6 in the region of the inlet opening 5 a of the nozzle 5 . Here also screens and rectifiers, not shown, are typically installed, which serve to improve the flow quality.

In the embodiment shown in FIG. 1, the contour of the closed prechamber 6 does not pass directly into the contour of the nozzle 5 , but rather the cross section of the inlet opening 5 a of the nozzle is smaller than the cross section of the prechamber 6 .

The nozzle 5 is arranged centrically to the pre-chamber 6 and the inlet opening 5 a circular symmetrical to the center line 9 of the flow 3 . This results in a uniformly large gap 7 between the outer circumference of the nozzle and the wall of the prechamber, due to the smaller cross section of the nozzle relative to the cross section of the prechamber. In each circular cross-sectional area of both the nozzle 5 and the antechamber 6 , the gap 7 is an annular gap.

At least the edge region 11 of the flow 3 of the medium 2 passes through this annular gap 7 as a partial flow and is thus guided past the inlet 5 a of the nozzle. The pre-chamber 6 extends in the flow direction beyond the inlet opening 5 a of the nozzle 5 addition, whereby the discharged flow fraction is also guided behind the annular gap 7 of the wall of the prechamber. Through the annular gap 7 in particular the boundary layer comprehensive edge portion 11 of the flow is peeled off, which would not overcome a pressure increase at the nozzle start due to their already made energy loss and therefore could replace. A separation would lead to vortex formation, which would reduce the flow quality in the nozzle 5 and subsequently in the measuring section 4 .

A transition of the boundary layer of the incoming flow in the contraction region of the nozzle does not take place due to the discharge. Instead forms after the discharge at the nozzle inlet 5 a from a new boundary layer of the flow 3 at the nozzle wall 5 b. As a result, the problem of vortex formation at the inlet of the nozzle, which could then be compensated again only via a corresponding contour of the nozzle with a correspondingly large length, does not occur. The passage of the boundary layer flow past the nozzle 5 allows the use of a short nozzle with a correspondingly large contraction, without the risk of a turbulent flow rising significantly.

In order to avoid influences of the peeled-off part of the flow on the remaining main flow entering the nozzle, the peeled-off part 8 of the flow is continuously discharged through an opening 12 into the plenum surrounding the measuring section 4 . It is important to ensure that within the antechamber 6 no backflow of the peeled flow is formed, which could affect the course of leading into the nozzle flow component. For this purpose, a corresponding line or the like can be arranged in the flow direction behind the gap 7 .

Of course, if necessary, it is also possible to support the continuous discharge of the peeled-off flow component 8 out of the prechamber into the plenum by further measures, such as, for example, the arrangement of a blower.

The front side of the border of the nozzle inlet opening 5 a is flowed through by the flow 3 and divides the flow into a guided into the nozzle 5 portion and guided past the nozzle, led part. The contour of the end face is designed to be favorable in terms of flow dynamics in order to minimize the formation of turbulences through the border.

In a closed flow guidance, a pipe provided for the peeled-off flow can also be continued through the plenum until after the measuring section and then open into the main line for the medium 2 in order to reunite the two streams.

The wall of the pre-chamber 6 is continued in the embodiment shown in Fig. 1 to about the middle of the nozzle 5 to the discharged partial flow without loss into a region behind the inlet opening 5 a of the nozzle 5 can promote and thus affect the flow before To avoid entry opening.

On the wall of the nozzle 5 , a new boundary layer flow is formed, which is energy rich enough in the immediate vicinity of the wall, in order to overcome even greater pressure increases without detachment.

The alternative shown in Fig. 2 corresponds to the principle shown in Fig. 1 for the same elements also Fig. 1 are therefore in Fig. 2 uses corresponding reference numerals.

The wind tunnel 1 shown in FIG. 2 also has an antechamber 6 , in which a medium 2 is guided in the flow direction 3 to a nozzle 5 . The contour of the nozzle 5 is continuous and tangential in the course of the wall of the pre-chamber 6 over. In the region of the inlet of the flowing medium 2 into the nozzle 5 , this has a wall region 13 with openings through the wall 5 b of the nozzle 5 . On the outside of the wall region 13 of the nozzle 5 , a suction fan 10 is arranged, with which at least the edge region 11 of the medium 2 formed by the boundary layer is conveyed as a partial flow 8 through the openings in the wall region 13 . The support of the discharge of the partial flow 8 through the suction fan 10 ensures that no backflow of the volume to be discharged can form in the nozzle 5 .

The openings in the wall portion 5 b of the nozzle 5 can be realized for example by using slotted or perforated plates.

Otherwise, the statements made on the embodiment according to FIG. 1 also apply to the variant shown in FIG. 2.

Claims (9)

1. A device for the separation-free guidance of a flow in a nozzle arranged in the flow, characterized in that in the inlet region of the nozzle ( 5 ) a device for separating the edge region ( 11 ) of the flow ( 3 ) is arranged. 2. Apparatus according to claim 1, characterized in that the nozzle ( 5 ) upstream of a pre-chamber ( 6 ) and the device is a partial flow discharge. 3. Apparatus according to claim 1 or 2, characterized in that the Teilstromausleitung is a fully formed between the outside of the nozzle ( 5 ) and the wall of the prechamber ( 6 ) formed gap. 4. Device according to one of claims 1 to 3, characterized in that the gap is an annular gap ( 7 ). 5. Apparatus according to claim 3 or 4, characterized in that the wall of the prechamber ( 6 ) via the inlet opening ( 5 a) of the nozzle ( 5 ) is continued beyond. 6. Apparatus according to claim 1 or 2, characterized in that the nozzle ( 5 ) in the inlet region openwork wall sections ( 13 ). 7. Apparatus according to claim 6, characterized in that on the outside of the nozzle ( 5 ) in the region of the perforated wall sections ( 13 ) at least one suction fan ( 10 ) is arranged. 8. Device according to one of claims 1 to 7, characterized in that the partial flow outlet is a bypass of the nozzle ( 5 ) and one of these downstream measuring section ( 4 ). 9. A method for improving the quality of flow in and to a nozzle of a flow device, in particular a wind tunnel, characterized in that the edge region 11 of the incoming flow (3) in the region of the inlet opening (5 a) of the nozzle (5) is separated from the nozzle flow ,