DE4111606C1 - Fluid flow distribution with flow obstacles - which deflect as diffusion two part-flows orthogonally to total flow direction - Google Patents

Abstract

The fluid distribution in obstructed flow gives diffuse multi-directional flow sense. A subflow, complete with obstacles, is deflected diffusely at right angles during the main flow, and another subflow is deflected out of the main flow direction (S). Pref. a gas distribution block is composed of corrugated plates (P1-6) to form hhalf-open ducts (K) on both sides at an angle to the main flow. The plates are so set to one another as to give closed ducts (KR,KL) and hhalf-open, intersecting ducts (CF). ADVANTAGE - Effective and uniform distribution with increased flow cross section.

Description

The invention relates to a method for distributing a flowing fluid, in which the fluid flows in the direction of flow Hitting obstacles diffusely from the direction of flow is distracted. The invention further relates to a Distribution block according to the preamble of claim 3 to carry out the procedure.

For example, it is known from DE 87 11 604 U1 shaped plates to form flow bodies for fluids. The shaped plates have oblique, half-open Channels and generally consist of a deep drawn plastic material. The semi-open channels are in the generally U-shaped or preferably V-shaped, wherein it is useful to have the bottom of the V-shaped channels over a to form a small width. It is known to block such juxtaposed plates as flow bodies use. The panels can be put together like this take place that the semi-open channels facing each other two neighboring plates each in the same direction run so that closed channels form. It is further known, especially for distribution purposes, the plates each by 180 ° so that the diagonally directed channels of two neighboring plates pointing towards each other cross and thus can not form closed channels. This arrangement is called a cross-flow arrangement, only to the  Crossing points of the semi-open channels pointing towards each other Fastening options for the adjacent panels surrender. With the cross-flow arrangement, the fluid is not - As with the closed channels - in a predetermined Directed, but at the intersection randomly distracted so that a certain distribution effect is achieved. It However, it has been shown that the cross-flow arrangement achieved distribution is not very evenly, but the flow direction starting from the fluid source represents strong preferred direction, so that there is a distribution approximately in the form of a Gaussian curve. The distribution effect is therefore limited.

The closed channel systems forming flow Bodies are completely unsuitable for distribution.

The flow in the cross-flow arrangement body problems occur in principle with all other distribution systems that have a usable flow allow throughput and their distribution effect not on one Backflow of the fluid is based on in principle the same way.

DE 28 38 159 C2 describes a device for distributing of a gas stream along an elongated inlet Gas treatment device known in the in the inlet pipe subdivisions arranged in the direction of flow are arranged. These subdivisions are continued by a point arranged at an angle to the gas guide tube electrostatic precipitator corresponding subdivisions. The gas is thus in part flows divided, diverted at an acute angle and enters parallel input channels of the electrical system filters. To have a more even distribution on the input To reach the channels of the electrostatic filter are the sub Divisions in the feed pipe with elevations the gas on the  Entrance openings in the interior of the deflection angle should distract. These are elevations in the direction of flow upstream of the input channels of the electrostatic filter.

The invention is therefore based on the object, a Ver drive the specified type and a distribution block of the ange given way to carry out the procedure, whereby an effective and even distribution of a flowing fluid should be achieved, with distribution the enlargement of the cross intersection of the flowing fluid is to be understood.

This object is achieved with a method of Type mentioned solved in that perpendicular to Total flow direction of the fluid is also a partial flow with the obstacles diffuse and another partial flow is directed from the direction of flow.

In the method according to the invention, a Fluids followed the path of distributing one Directional deflection of the fluid, which is unsuitable for fluids with the diffuse deflection of the fluid from the flow direction to combine to create a more even To achieve distribution. It is clear that the one achieved Effect is particularly good when the fluid is in a variety of Partial streams is divided, which are roughly equal shares diffused and directed from the direction of flow will.

The process according to the invention can be carried out with a Run manifold block made up of a variety of wave-shaped plates, each on both sides in Form flow direction diagonally directed, semi-open channels, is built up when the plates are so together in the block are set that both closed channels and themselves intersecting semi-open channels are formed.

The closed channels and the are preferably crossing semi-open channels alternately formed.  

A particularly useful training provides that the closed channels alternately to the different sides are directed and that between the closed channels intersecting half-open channels are formed.

The distributor block according to the invention can be identified from identical Assemble shaped plates.

It is advantageous if the channels of the plates with the Flow direction an angle of 45 °, preferably of form about 30 °.

The distributor block according to the invention causes an expansion of the fluid flow essentially in a plane in which the sloping channels are arranged. Beyond that a distribution in the plane perpendicular to it desired, this can be done by two consecutive 90 ° rotated distributor blocks can be reached.

The invention is illustrated below with reference to the drawing presented embodiments explained in more detail.

It shows:

Fig. 1 is a schematic representation of the succession of molded plates in a manifold block,

FIG. 2 shows a top view of the distributor block assembled according to FIG. 1, FIG.

Fig. 3 shows two examples of the use of distribution blocks according to the Invention.

Fig. 1 illustrates schematically six plates P 1 to P 6 , which are preferably made of rigid PVC as deep-drawn, corrugated plastic plates and thereby have obliquely running semi-open channels K. With the flow direction assumed from bottom to top in FIG. 1, the channels K form an angle α of 30 °. The plates are symmetrical with respect to their central plane and can therefore be used on their front and back. By rotating the plates through 180 °, the channels pointing towards the viewer in FIG. 1 run to the left.

The construction of the distributor block with the plates P 1 to P 6 takes place in the exemplary embodiment according to FIG. 1 from the front to the rear through two plates P 1 , P 2 , both of which have channels directed to the right. The plates P 1 and P 2 are glued to one another in such a way that closed channels KR form, which thus point to the right.

The third plate has channels K pointing to the left. The semi-open channels of the second and third plates P 2 and P 3 pointing towards one another thus intersect, so that a cross-flow arrangement CF is formed between the second and third plates P 2 and P 3 .

The fourth plate P 4 in turn has channels K pointing to the left and, together with the third plate, forms closed channels KL pointing to the left.

The fifth plate is again arranged with channels K pointing to the right, so that a cross-flow arrangement CF is formed between the fourth and fifth plates P 4 and P 5 . Since the sixth plate P 6 in turn has channels K pointing to the right, it forms channels KR directed to the right together with the fifth plate.

The construction scheme of the manifold block of FIG. 1 is therefore KR-CF-CF-KL-KR-CF-CF-KL, etc ..

Fig. 2 shows a view of the underside of the manifold block formed according to Fig. 1 and illustrates that the plates P 1 to P 6 have approximately V-shaped channels K, each having a flat bottom B, on which they with the adjacent plate P 1 to P 6 can be connected , in particular can be glued. The gluing with panels with channels K directed in the same way can take place in strips over the entire surface of the floor, while the bonding with adjacent panels with channels K directed differently can naturally only take place at the crossing points of the floors B.

Fig. 2 shows the course of the edges of the channels K, so that it can be seen that the plates P 1 and P 2 have right-facing channels K and together form the closed, right-facing channels KR. The channels K cross between the second and third plates P 2 and P 3 , so that the cross-flow arrangement CF is formed, as has already been explained with reference to FIG. 1.

The distributor block shown in FIG. 2 can have a length of 120 cm and a width of 60 cm, for example.

Fig. 3 shows two application examples for the aeration of waste water, in which air is bubbled from below into the water through distributor nozzles V. The bubbled air is distributed through the distributor block in the direction of the length L of the distributor block corresponding to the angle α of the channels K over the height H of the distributor block. In the case of a plurality of distributor nozzles V, as shown in the right part of FIG. 3, the arrangement of the distributor block is expediently chosen such that the channels K widening the air flow adjoin one another.

Because of the construction of the distributor block, the air flow is expanded only in the direction of the length L of the distributor block, but not in the direction of the width W ( FIG. 2) of the distributor block. If an expansion of the air flow in the direction of the width W is also desired, it is expedient to connect two distributor blocks rotated by 90 ° to one another in the flow direction, that is to say to arrange them one above the other in a flow direction from bottom to top.

The air flow emanating from the distribution nozzles V is divided into a plurality of partial flows in the distribution blocks, and partly reaches closed channels KR directed to the right with respect to the length L of the distribution block, partly into left-pointing channels KL and partly into cross-flow - Arrangements CF. The cross-flow arrangements CF result in a distribution with a focus on the direction of flow starting from the distributor nozzles V. Partial flows are directed to the right and left of it through the closed channels, so that the greatly reduced deflection in this area is compensated for by the cross-flow arrangements CF. It is important that the closed channels KR and KL are available over the entire width of the air stream that emanates from the distributor nozzle V, for which purpose the strictly alternating arrangement KR-CF-KL-CR shown in FIGS. 1 and 2 is available etc. is advantageous.

Claims (8)

1. A method for distributing a flowing fluid in which the fluid meets obstacles in the direction of flow (S) and is diffusely deflected from the direction of flow, characterized in that perpendicular to the overall direction of flow of the fluid simultaneously a partial flow with the obstacles diffuse and another partial flow is deflected from the direction of flow (S). 2. The method according to claim 1, characterized in that the Fluid is divided into a large number of partial flows, which are roughly equally diffuse and directed the flow direction (S) are deflected. 3. Distribution block for a flowing fluid, in particular for gases, made up of a plurality of shaped plates (P 1 to P 6 ) which, wave-shaped, on both sides in each case in the flow direction (S) obliquely directed, half-open channels (K) for Implementation of the method according to claim 1 or 2, characterized in that the plates (P 1 to P 6 ) are placed against one another in such a way that both closed channels (KR, KL) and intersecting semi-open channels (CF) are formed. 4. distributor block according to claim 3, characterized in that the closed channels (KR, KL) and the crossing semi-open channels (CF) alternately are formed. 5. distributor block according to claim 4, characterized in that the closed channels (KR, KL) alternate to the different sides and that between the closed channels (KR, KL) each intersecting semi-open channels (CF) are formed. 6. Distribution block according to one of claims 3 to 5, characterized in that the half-open channels (K) of the plates (P 1 to P 6 ) with the flow direction (S) form an angle α of 45 °. 7. Distribution block according to claim 6, characterized in that the semi-open channels (K) of the plates (P 1 to P 6 ) with the flow direction (S) form an angle α of approximately 30 °. 8. distributor block arrangement, marked by two 90 ° around their in the direction of flow (S) lying axis rotated to each other, in the direction of flow (S) distribution blocks arranged one behind the other according to one of claims 3 to 7.