EP1882786A1 - Pipe elbow for a sanitary conduit - Google Patents

Abstract

The elbow (1) has a flow divider (5) arranged at an inner side (3) of a vertical region (1a), and drilling down a film flow of water and enabling pressure balance in the flow. The flow divider is arranged on a side of an outlet, and is extended in a flow direction over a half of the inner side. The flow divider comprises a radial thickness, which suits to a thickness of the film flow and is smaller than 2 centimeters. The divider has an edge (5a), which is extended radially.

Description

The invention relates to a deflecting bend for a downpipe for discharging a two-phase flow of water and air, having a substantially vertically extending region, an arcuate region adjoining this and an essentially horizontal outlet.

Such deflector are also called elbows and serve mainly to dissipate in multi-storey buildings, the wastewater of sanitary appliances, such as sinks, toilets and the like. In the downpipe, when the siphons of these apparatuses are emptied, a two-phase flow of water and air is formed. It has long been known that the flow guidance in such downpipes and in particular in the deflection bend is not optimal. It may come in the downpipe in particular to form a negative pressure or an overpressure and vibrations. There are already several proposals in the art to improve flow control.

By the CH 388 209 A an air separator for water and sewage pipes is proposed. In a nozzle for this purpose, an organ is arranged, which is intended to deflect the water entering and braking in such a way that entrained air separates out and flows away through a breather. This organ is intended to produce a rotational movement in the jet, which is intended to promote the venting. The beam deflector directs the incident Water jet for the purpose of braking and venting. The nozzle requires a connection for an air outlet line.

The CH 533 793 A discloses a branch piece for drain lines, which has a shunt connection in the region of lateral connections.

By the CH 598 430 A a fall brake for drainage water in a vertical wiring harness is proposed. With the fall brake a strong turbulence is to be generated, which largely destroys the kinetic energy of the water, so that the flow velocity of the water immediately below the fall brake is much smaller than immediately above it. The fall brake is formed by a deflection rib, which is directed obliquely downwards. However, such a fall brake or reduction of the energy of the flow is disadvantageous because residues in the pipeline can be washed away less effectively.

The invention has for its object to provide a deflection arc of the type mentioned, with which the disadvantages mentioned can be avoided. In particular, the formation of a negative pressure in the downpipe should be largely avoided. Nevertheless, the flow should lose as little energy as possible, so that residues in the pipeline can be effectively washed away.

The object is achieved in a generic deflection arc in that a flow divider is arranged on the inside of the substantially vertical region, which ruptures a film flow of the water and thereby allows pressure equalization in the flow. The invention is based on the finding that in a downpipe, the water flows as a film flow on the inside of the line down and that in the arcuate region of this film flow forms a kind of curtain, which prevents the air at the outlet. With the flow divider according to the invention, this film flow is torn immediately above the sheet, so that an opening forms in this film flow, through which a pressure equalization is possible. This also prevents a noise-generating vibration of the air. The energy loss at this flow divider is comparatively small, leaving residues in the pipeline can be washed away effectively. The inventive deflection arc is suitable for bends of 90 ° but also for elbows with a smaller deflection, for example of 88.5 °. It is also suitable for different downpipes, for example for different diameters and heights and in particular for multi-storey buildings. Experiments have shown that usually a complete pressure equalization can be achieved. The invention has the further advantage that the power of the downpipe can be increased because the load is smaller.

According to a development of the invention, the flow divider is arranged above the arcuate region. The opening formed by the flow divider then preferably extends in the region of the arc or the curvature. The cylindrical film flow then passes into a channel flow after the exit, the water then runs after the exit similar to a channel at the bottom of the pipe.

According to a development of the invention, the flow divider is arranged on the said inner side on the side of the exit. This results in a particularly suitable Strömungsfiihrung.

According to a development of the invention, the flow divider extends as seen in the flow direction at least over half of the inside. As a result, the flow guide can be further improved. It can be avoided in particular that the film flow closes after the flow divider again.

A further improvement in the course of the flow is achieved when the flow divider has essentially the shape of an inverted V or the upper edge has a miter.

A particularly cost-effective production is possible if, according to an embodiment of the invention, the flow divider is formed on the inside of the vertically extending region. However, according to a development of the invention, the flow divider can also be produced separately and, for example, welded on.

According to a development of the invention, the flow divider has an upper comparatively sharp edge, from which V-shaped two arms extend downwards. The opening angle of these two arms is preferably in the range of 50-70 °, more preferably between 55 and 65 ° and is still preferably about 60 °. This results in a particularly efficient formation of an opening in the film flow.

Said two arms have a cross-sectional area preferably less than 3 cm ² , preferably less than 2 cm ² and in particular a cross-sectional area of about 1 cm ² . The cross section may be rectangular, but also have another suitable shape.

Further advantageous features emerge from the dependent claims, the following description and the drawings.

Figur 1

schematisch eine räumliche Ansicht eines erfindungsgemässen Umlenkbogens, wobei aus zeichnerischen Gründen die Wandung als durchsichtig dargestellt ist,

Figur 2

eine weitere Ansicht des erfindungsgemässen Umlenkbogens gemäss Figur 1,

Figur 3

schematisch die Strömung in einem Umlenkbogen nach dem Stand der Technik,

Figur 4

schematisch der Verlauf der Strömung in einem erfindungsgemässen Umlenkbogen,

Figur 5

eine weitere Ansicht eines Umlenkbogens gemäss Figur 3 und

Figur 6

eine weitere Ansicht des erfindungsgemässen Umlenkbogens zur Erläuterung des Strömungsverlaufes.

An embodiment of the invention will be explained below with reference to the drawing. Show it:

FIG. 1

1 is a schematic view of a spatial view of a deflection arc according to the invention, the wall being shown as transparent for reasons of drawing,

FIG. 2

a further view of the inventive deflection bend according to Figure 1,

FIG. 3

schematically the flow in a deflection bend according to the prior art,

FIG. 4

the course of the flow in a deflection bend according to the invention,

FIG. 5

a further view of a Umlenkbogens according to Figure 3 and

FIG. 6

a further view of the inventive deflection bend to explain the flow path.

The deflector 1 shown in Figures 1 and 2 forms a lower portion of a downpipe, not shown here, which is connected to one or more sanitary apparatus, each having a siphon. The deflecting sheet 1 can be installed for example by mirror welding or with suitable sleeves in the downpipe. The water to be discharged flows according to Figure 1 in the direction of the arrow 6 in a continuous channel K and leaves the deflecting arc 1 in the direction of arrow 7 substantially horizontally through an outlet opening 2. At this outlet opening 2, a disposal line, not shown here is connected. This can also be slightly inclined to the horizontal.

The deflection arc 1 has a wall 4 which forms a vertical region 1a and an arcuate region 1b of the deflection arc 1. In the vertical region 1a, the cross section is substantially circular. The arcuate portion 1b forms a deflection of 90 ° or even slightly less than 90 °, for example about 88 °. The radius of curvature in the arcuate region 1b can be different and is for example 10 cm. The inner diameter of the channel K is dependent on the required discharge capacity and is for example 10 cm.

The wall 4 forms an inner side 3, on which, according to FIGS. 1 and 2, a flow divider 5 is arranged. This serves to break up a film flow 12 forming in the channel K in front of the arcuate region 1b, thereby forming the opening 14 in the film flow 12 shown in FIG. The film flow 12 is shown schematically in FIGS. 4 and 6. This forms immediately after the inflow of water 11 in the deflection arc 1 or even above this in the down pipe. According to FIG. 4, the water 11 flows essentially horizontally into the deflecting bend via a connecting piece 10. With the water 11 at the same time air 13 flows into the deflection arc 1 and in the down pipe. In the deflection arc 1, this forms a two-phase flow of water and air. The water 11 forms on the inner side 3 the said film flow 12, which has a comparatively small thickness compared with the inner diameter of the deflection arc 1. This is for example 1 cm. But it can also be slightly thicker, for example 2 cm or slightly thinner. Within this Film flow 12 is air 13 which has a lower flow velocity than the water in the film flow 12.

The effect of the flow divider 5 is explained in more detail below with reference to FIGS. 3 to 6, wherein FIGS. 3 and 5 each show a deflection bend 8 of the prior art. The deflecting bend 1 or 8 is assumed to be transparent for reasons of drawing.

In the prior art bend bow 8 shown in FIG. 3, the water flows in the direction of the arrow 9 into the channel K and forms the film flow 12 ', which surrounds the air 13'. Due to the film flow 12 ', the arcuate region 1b forms a type of curtain 17, which forms above all with larger thicknesses of the film flow 12'. This curtain 17 acts as a barrier to the passage of air. Since pressure equalization is difficult, a negative pressure can form in the deflection arc 8. In the air 13 'can also build up vibrations that generate noise. The effects are different depending on the type of film flow 12 '. This film flow 12 'can be turbulent or largely laminar and, as mentioned, of different thickness. However, the disturbances in the two-phase flow of water and air are usually considerable. They affect the connected devices. They can also affect the elimination of residues.

In the deflection bend 1 according to the invention, the film flow 12 impinges on the flow divider 5, as FIGS. 4 and 6 show. The flow divider 5 runs along the inner side 3 and that on the side of the outlet opening 2. The flow divider 5 has an upper radially extending edge 5a, which may be rounded or comparatively sharp. From this edge 5a, two arms 5b extend downwardly in a V-shape. The shape of these arms 5b is similar to the top of a miter. The arms 5b do not run in a plane, but in the surface of a cylinder formed by the inside 3. The arms 5b are connected at the top according to FIG. 6 and each have a lower end 5c. Preferably, the arms 5b are symmetrical to the vertical. The opening angle of the arms 5b may be different. Experiments have shown that a particularly favorable flow profile is achieved when this Angle between 50 ° and about 70 °. Preferably, this angle is 55 to 65 °. An optimal flow results in particular at an angle of about 60 °. The radial thickness and also the cross section of the arms 5b may be different. Preferably, this thickness is chosen so that it substantially corresponds to the thickness of the film flow 12. The thickness is for example less than 2 cm and typically about 1 cm. But here are also larger or smaller thicknesses conceivable. The cross-sectional area of the arms 5b is for example about 1 cm ² and is in particular angular, for example rectangular. The cross-sectional area may be the same over the length of the arms 5b, but it is also conceivable to change this cross-sectional area.

The film flow 12 is divided at the edge 5a and the water flows in partial flows respectively on an outer surface 5d (FIG. 1) from this edge 5a to the corresponding end 5c. From the edge 5a tears the film flow 12, wherein the above-mentioned opening 14 is formed. It is essential that this opening 14 does not close again immediately after the flow divider 5, but extends downwards into the arcuate region 1b. The cylindrical film flow 12 is thereby converted into the channel flow 16 shown in Figure 4, which extends in the lower region of the outlet opening 2 and corresponding to the bottom of the connected pipe. Above this channel flow 16 is air, which is connected through the opening 14 with the air 13 in the vertical region 1b. As a result, a pressure equalization is possible at any time and pressure fluctuations in the air 13 and accordingly also in the connected apparatus can be avoided.

The arms 5b are connected as mentioned above and extend downwardly from the edge 5a. As can be seen in FIG. 4, the arms 5b extend as far as the projection of the arcuate region 1b. They extend in the pipe cross-section seen in the half pipe circumference. This extension can also be slightly exceeded or undershot. By this extension, the continuous existence of the opening 14 can be ensured particularly effective and also reliably forms the above-mentioned channel flow 16. Turbulence in the arcuate region 1b and thus pressure fluctuations in the pipe system can thus be effectively avoided. Since such pressure changes or pressure fluctuations, the resilience of the case strand or limit the downpipe, it is possible with the inventive deflection bend 1, to increase the power at the same pipe diameter. Conversely, it is possible to connect the same apparatus to a down pipe with a smaller inner diameter than before.

LIST OF REFERENCE NUMBERS

1

reversing curve

1 a

vertical area

1b

arcuate area

2

outlet opening

3

inside

4

wall

5

flow divider

5a

edge

5b

poor

5c

lower end

5d

outer surface

6

arrow

7

arrow

8th

Deflection bend (prior art)

9

arrow

10

management

11

water

12

film flow

13

air

14

opening

15

partial flow

16

gutter flow

17

"Curtain"

K

channel

Claims (13)

Deflection bend for a downpipe for discharging a two-phase flow of water and air, having a substantially vertically extending portion (1a), an adjoining this arcuate portion (1b) and a substantially horizontal outlet (2), characterized in that on the inside (3) of the substantially vertical region (1a), a flow divider (5) is arranged, which ruptures a film flow (12) of the water (11) and thereby allows pressure equalization in the flow. Deflection bend according to claim 1, characterized in that the flow divider (5) is arranged above the arcuate region (1b). Deflection bend according to claim 1 or 2, characterized in that the flow divider (5) on the side of the output (2) is arranged. Deflection bend according to one of claims 1 to 3, characterized in that the flow divider (5) seen in the flow direction extends over at least half of the inner side (3). Deflection bend according to claim 4, characterized in that the flow divider (5) extends beyond half of the inner side (3). Deflection bend according to one of claims 1 to 5, characterized in that the flow divider (5) has substantially the shape of an inverted V or the upper edge of a miter. Deflection bend according to one of claims 1 to 6, characterized in that the flow divider (5) on a wall (4) is integrally formed. Deflector according to one of claims 1 to 7, characterized in that the flow divider (5) has an upper edge (5a) from which extend two arms (5b) downwardly, which lie in a cylindrical surface. Deflection bend according to claim 8, characterized in that said edge (5a) extends radially. Deflection bend according to one of claims 1 to 9, characterized in that the flow divider (5) has a radial thickness which substantially corresponds to the thickness of the film flow (12), said thickness is preferably less than about 2 cm. Deflection arc according to one of claims 8 to 10, characterized in that the two arms (5b) enclose an angle of 50-70 °, preferably 55-65 ° and in particular an angle of about 60 °. Deflection bend according to one of claims 8 to 11, characterized in that the two said arms (5b) have a cross-sectional area less than about 2 cm ² . Deflection bend according to one of claims 1 to 12, characterized in that the flow divider (5) in the film flow (12) forms an opening (14) which extends downwards into the arcuate region (1b).

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