NL7811364A - DIFFUSOR IN PARTICULAR WITH LARGE TOP ANGLE. - Google Patents

Description

^ 4 'N.O. 26,870

Netherlands Organization for Applied Scientific Research for the benefit of Industry, Trade and Traffic, in The Hague.

Diffuser in particular with large barrel angle.

The invention relates to a diffuser for a flowing medium, with an apex angle greater than 15 ° (three-dimensional) and 20 ° (two-dimensional), respectively, in which an inner diffuser is placed symmetrically with respect to the center line and the center plane, respectively, such that 5 Both diffusers formed a significant part of the incoming flow.

A diffuser of this type is known from German Offenlegungsschrift 2,436 * 456, which describes a diffuser with a relatively large apex angle. It is well known that, for both compressible and non-compressible flowing media, a top angle of the diffuser greater than about 15 ° should not be exceeded in order to prevent release of the flow from the diffuser wall. As soon as detachment occurs, vortices and backflows are created in the region between the diffuser wall and the released flow thereof, causing large friction losses, so that the desired conversion of the velocity of the medium entering the diffuser into pressure does not proceed optimally. A far-reaching conversion of the quick guide energy into pressure is therefore only possible with diffusers which, due to the maximum top angle of 15 °, have a length which is many times the diameter of the supply line. In practice, these cannot usually be accommodated due to lack of space, so that the flow proceeds with greater losses than would be possible under optimal conditions. A known solution to this problem consists in that the diffuser is subdivided into a number of sub-diffusers, each of which has an apex angle of approximately 15 °. As a result, 7811354 '2.

indeed a shorter construction length is achievable, but the increase in the number of walls increases the losses due to the wall friction. Such a possibility is described in German patent 869,281. In practice, however, the shortening of the diffuser achieved in this way is often still insufficient, while the construction of such a multiple diffuser is complicated and expensive.

In the aforementioned German Offenlegungsschrift 2,436,456 a diffuser is described, which is indeed much shorter; it is stated that a top angle is reachable up to 120 °. For this purpose, an inner cone is placed in the diffuser, which base connects to the end of the diffuser and is perforated such that the flowing medium in the gap between the diffuser and the cone deflects and then gradually through the perforations to the interior of the diffuser. the inner cone branches. The main stream is thus divided into a large number of substreams, each of which bends inwards and expands freely. Too little data is provided in said publication to evaluate the effectiveness of the conversion of speed to pressure in this construction. The division of the main flow into as many ctel flows as there are perforations, however, suggests that relatively large vertebral losses will occur within the inner cone. Moreover, with larger dimensions, the construction is relatively expensive. Moreover, the device described will, at a larger apex angle, be very similar to another known solution, which is mainly used in wind tunnels for rectifying and expanding the flow before its entry and the so-called sus chamber. Here, a grid or mesh is placed perpendicular to the flow direction at the end of a diffuser with a large top angle, while some gratings or meshes may still be placed along the length of that diffuser. Such a device gives an excellent rectification, however, with virtually no conversion of speed to pressure. It is expected that the device described in the German Offenlegungsschrift will have a comparatively small useful effect in this respect.

78 1 13 8 4 3

The object of the invention is to obtain a much better useful effect of the conversion for a diffuser with a comparatively large top angle using a simple construction.

According to the invention, the diffuser described in the preamble is characterized in that the walls of the inner diffuser run substantially parallel to those of the outer diffuser and are smooth and closed, that the gap between the two diffusers is also open on the outflow side. the inner diffuser on its inlet side is completely open and has an inlet passage which is approximately half through the passage of the supply line at the location of the transition to the outer diffuser.

Because diffusers are often mounted on or near the inflow opening in an apparatus of any shape, it may be necessary for the diffuser to have a cross-section of any shape. This naturally includes round cross sections and rectangular and all possible intermediate shapes. In principle, the invention relates to all these forms. The operation of the device according to the invention is unexpectedly good, even when the speed and the incoming flow are very uneven. Namely, asymmetrical velocity profiles in the feed stream, for example as a result of bends, have only a small influence on the operation of the diffuser according to the invention. The easy-to-manufacture non-perforated inner diffuser is attached to it with some, possibly streamlined spacers, symmetrically with respect to the center line of the outer diffuser.

According to a preferred embodiment, the inner diffuser, viewed in flow direction, is shorter than the outer diffuser.

The length of the inner diffuser will then be about 1/3 to about 30 3/4 of the length of the outer diffuser.

Furthermore, flow is favored when viewed in the flow direction, the inflow opening of the inner diffuser is some distance downstream from the start of the outer diffuser. 35

According to a further advantageous embodiment, the inner wall of the inner diffuser is profiled, viewed in flow direction. Thereby a more uniform expansion and a better conversion of speed to pressure is achieved of that part of the flow that flows through the inner diffuser. However, this is at the expense of a complicated embodiment. 5

Something similar can be achieved by arranging so-called vortex generators on the inner surface of the inner diffuser near the inflow edge such that they generate equally spaced left and right rotating corkscrew vertebrae. These vortices prevent the formation of a boundary layer and the risk of the flow coming loose on the inner wall of the inner diffuser, so that a better conversion of speed into pressure takes place. These generators can be in the form of small blades or baffles positioned obliquely to the flow direction, but they can also be arranged as grooves or channels in the material of the inner diffuser, for instance in case a profiled inner wall is used.

The operation of this invention may be based on the portion of the flow, which is deflected outwardly between the outer and inner diffusers, flowing at the end of the inner diffuser as a Cane beam along the inner wall of the outer diffuser and the subsequent line . By ejector action, this Cane jet draws in the part of the flow that has passed through the inner diffuser so that it expands quickly and with little loss of pressure.

The diffuser according to the invention will mainly be used from a top angle of approximately 15 ° below which the installation of an inner diffuser makes sense only in the case of uneven inflow. 30

Although the design becomes more expensive, the diffuser according to the invention is also applicable when, viewed in the direction of flow, the outer and inner diffusers of a circular cross-section gradually change to an elliptical, oval, rectangular or square cross-section, or vice versa. The importance of this has already been pointed out before.

The invention will be further elucidated on the basis of the following figure description as an example.

Fig. 1 shows a longitudinal passage through the diffuser according to the invention.

Fig. 2 shows a cross-section of an alternative embodiment of the diffuser according to the invention, in the top half of the figure in three-dimensional embodiment, in the lower half in two-dimensional embodiment.

Fig. 3 shows a view of the diffuser of FIG. 2, again three-dimensional and two-dimensional.

Fig. 1 shows an outer diffuser 1 with apex angle a, 10 which is considerably greater than 15 °. The supply of the flowing medium takes place through a cylindrical supply line 2, which at 11 passes into the outer diffuser 1 without any significant rounding. the expanded medium diffuser 1 flows out via a cylindrical discharge pipe 3 * The transition between the outer diffuser 1 and the discharge pipe 3 is made at 12 practically without rounding. Instead of on the discharge pipe 3, the diffuser 1 can be directly connected to a device. In the outer diffuser. 1, the inner diffuser 4 is arranged symmetrically with respect to its centerline. Beze is firmly anchored in the outer diffuser using a number of spacers 5.

It is advantageous to make the spacer supports 5 streamlined. Instead of the spacers 5, the inner diffuser can also be localized in the outer diffuser 1 in another way.

The wall of the inner diffuser 4 extends substantially parallel to the wall of the outer diffuser 1. Between the two walls there is a gap 13 which has a substantially constant width over its entire length, viewed in flow direction. The inflow opening 9 of the inner diffuser has a very specific width or diameter ratio with respect to the width or diameter of the supply line 2. This ratio differs depending on whether the diffuser is two-dimensional or three-dimensional. The length 1 of the inner diffuser 4 is smaller than the length L of the outer diffuser 1. The inflow opening 9 is located a certain distance downstream of the kink 11 between the supply line 7811364 6 and the outer diffuser 1. This distance a again depends on whether the diffuser is two- or three-dimensional, and also depends on the size of the top angle of the diffuser. Likewise, the ratio of the heath lengths 1: L depends on said apex angle of the diffuser. ^

With reference to the graphs according to Figs. 4 and 5, it is schematically indicated in Fig. 1 that the inflow through the conduit 2 to the diffuser is partly characterized by a certain static pressure P and a speed V.

Fig. 2 shows a cross-section of a diffuser, * Iq, which shows some refinements with respect to that of Fig. 1. In the top half of the figure, a three-dimensional diffuser with an oval-shaped cross-section is shown, while in the bottom half a cross-section through a rectangular diffuser is shown. The inner diffuser 4 is provided on its inner side with a wing profile in order to better conduct the flow through the interior of the inner diffuser.

The flow will release the wall 6 less quickly than according to the simpler embodiment of fig. 1. It is important here that the thrust point 9 of the inner diffuser meets the same requirements as previously described, inter alia with regard to its distance a downstream of from the beginning of the outer diffuser 1 and in terms of its diameter or width ratio to the diameter or width of the supply line 2. Otherwise, the diffuser of FIG. 2 corresponds to that of FIG. 1.

In fig. 3 is a right view of the diffuser of fig.

2, also in three-dimensional circular design in the top half and rectangular two-dimensional in the bottom half. The rectangular embodiment in the lower half is closed at both ends by a wall 8, only one of which is shown. The total length of the diffuser is H.

In both Figures 2 and 3 a further alternative is shown, namely a device for generating cork-trigger vertebrae (vortex) at the inflow of the inner diffuser. These vortex generators 7 can have the form 7811364

Claims (6)

1. Diffuser for a flowing medium, with an apex angle greater than approximately 15 ° (three-dimensional) and 20 ° (two-dimensional), in which an inner diffuser is placed symmetrically with respect to the centerline and the center plane, respectively, which is positioned through the intermediate the slit formed in both diffusers conducts an important part of the ingress flow, characterized in that the walls of the inner diffuser (4) run substantially parallel to those of the outer diffuser (1) and are smooth and closed, the slit being (13) between the two diffusers (1, 4) is also open on the outflow side, and that the inner diffuser (4) on its inflow side (9) is fully open and has an on-flow passage which amounts to approximately half of the passage of the supply line / at the location of the transition to the outer diffuser (l). Diffuser according to claim 1, characterized in that - viewed in flow direction - the inner diffuser is shorter than the outer diffuser, the length (l) of the inner diffuser from about 1/3 to about 3/4 of the length (l ) 30 of the outer diffuser. Diffuser according to one or more of the preceding claims, characterized in that - viewed in flow direction - the inflow opening of the inner diffuser is at a distance (a) of approximately 0.05 - 0.2 D (three-dimensional) or approximately 0.05 - 0.2 B (two-dimensional) downstream of 7311354 from the start of the outer diffuser. Diffuser according to one or more of the preceding claims, characterized in that - viewed in flow direction - the inner wall of the inner diffuser is profiled. 5 Diffuser according to one or more of the preceding claims, characterized in that vortex generators (corkscrew-swirl generators) are arranged on the inner surface of the inner diffuser near the inflow edge in such a way that they are equally spaced about around 10 left and right rotating corkscrew vortices, and that these generators consist of vanes or vanes and / or are provided as grooves or channels in the material of the inner diffuser. 6. Diffuser according to one or more of the preceding claims, characterized in that - viewed in the direction of flow - the outer and inner diffusers of a circular cross-section gradually merge into an elliptical, oval, rectangular or square cross-section, or vice versa. 7811364