DE202008003044U1 - End fittings - Google Patents

Abstract

A filtering inlet (4) fits near one cross-sectional enlargement (3) and/or directly on it while bordering on a side opposite a reduction of area (2). A filtering outlet (4) fits near another cross-sectional enlargement and/or on it while directly bordering on a side opposite the reduction area. An independent claim is also included for a drinking and domestic water system with floor-by-floor and riser pipe branching.

Description

The The present invention relates to a connection fitting for connecting a Ring line with at least one consumer on one floor or riser pipe with connectable to the strand inlet and outlet openings and intermediate inlet and Ausführelöffnungen through a cross-sectional constriction are separated from each other, wherein the cross-sectional constriction of two enclosed in the direction of the inlet and outlet opening gradually enlarging cross-sectional extensions is.

in the Range of drinking or service water systems in particular to prevent contamination in the drinking or service water pipes known to provide a connection fitting of the aforementioned type to in one over this connection fitting connected ring line with removal of Drinking or service water over one in the flow direction subsequently arranged consumers to a loop flow to achieve. In this case, a partial flow of the strand at the Ausfädelöffnung the Outlet fitting led out and over the ring line to the at least one consumer connected to the loop guided. The ring line opens in the threading opening of the End fittings. In mainstream direction the threading hole is one Preceded cross-sectional constriction, which acts like a nozzle and between the Aus- and Einfädelöffnung a Pressure difference causes by which at a flow in the strand is also in the loop a flow is generated. The main flow direction is in the sense of the present invention synonymous with the axial extension direction to understand the strand. As a strand in the sense of the present Invention is understood to mean any main line, regardless of whether this extends within a floor and within the floor several consecutively arranged wet cells over each a ring pipe supplied with drinking or service water, or as a riser cabinet For example, in several floors superimposed wet cells connects with each other.

From the DE 39 19 074 For example, a connection fitting of the aforementioned type is known as part of an ultrapure water supply system. In this prior art connection fitting the recirculated from the loop in the strand loop flow is introduced at an angle of about 90 ° to the main flow direction in the connection fitting. The return of the loop flow takes place via a threading opening arranged in a cross-sectional constriction. The threading opening is therefore provided in an area with the lowest pressure. Since the cross-sectional constriction acts in the manner of a Venturidü se and causes the above-described pressure difference between the extraction and Einfädelöffnung, upon removal of drinking or service water directed from the Ausfädelöffnung to the Einfädelöffnung flow is generated. The generated flow is therefore directional. This is the from the DE 39 19 074 previously known connection fitting for drinking or service water systems unsuitable, in which a flow through the strand is provided as needed in one or the other direction.

From the date of the applicant EP 1 882 784 is also a connection fitting of the aforementioned type known. The from the EP 1 882 784 The prior art connection fitting differs from the above-described connection fitting substantially in that the threading is provided in the region of a diffuser and the recirculation flow recirculated from the loop line is introduced at an angle of not more than 75 ° to the main flow direction. This connection fitting is also unsuitable for a drinking or service water system with intended flow reversal, as in the case of flow reversal desired in the loop purge effect is drastically reduced or no longer exists, so that a flushing of subsequent connected to the strand loops can not be guaranteed safely. Such a flow reversal can occur when the floor or riser pipe is also formed as a ring and the removal of drinking or service water in one of the connected to the floor or riser ring lines a flow in both the upstream and the downstream Connecting fittings causes.

Of the present invention is based on the problem, a connection fitting to connect a loop with at least one consumer at one floor or specify a riser or ring, with a reliable flushing effect the ring line even with flow reversal can be achieved, and to provide a drinking or service water system, which used such a connection fitting.

To solve the above problem, the present invention proposes a connection fitting having the features of claim 1 and a drinking or service water system having the features of claim 15. The connection fitting according to the invention is distinguished from the generic connection fitting by a threading, which is adjacent in the region of a cross-sectional widening and / or immediately adjacent to this on the opposite side of the cross-sectional constriction, and by a Ausfädelöffnung, in the region of the other cross-sectional widening and / or at this on the Cross-sectional constriction opposite side immediacy bar adjacent is arranged. The inventive arrangement of the inlet and Ausfädelöffnung allows a flow through the connection fitting in both directions such that a desired flushing effect of the ring lines is ensured regardless of the prevailing flow in the strand. In other words, when removing drinking or service water to a consumer all in the flow direction in front of the strand connected ring lines can be flushed. It has been found to be advantageous that a conditional by the inventive arrangement of the inlet and Ausfädelöffnung pressure loss within the connection fitting, whereby several in the main flow direction one behind the other arranged connection fittings are tunable to each other taking into account a prevailing operating pressure in the strand, so that a sufficient Flushing effect of all loops remains guaranteed. In particular, it has proved to be advantageous for reducing the pressure difference to arrange the Einfädelöffnung in the main flow direction in an area immediately behind the cross-sectional widening, ie in an area in which would normally be expected that the line pressure corresponds to the pressure at the Ausfädelöffnung, whereby a flushing the ring line would be unavailable for lack of pressure difference. However, it has been found that the flow in the region lying immediately behind the cross-sectional widening has a lower pressure than at the discharge opening, so that a pressure difference can be achieved which can ensure a rinsing effect of the loop. Specifically, the cross-sectional constriction upstream of the threading aperture acts as a nozzle, thereby introducing the flow into the downstream diffuser at an increased rate. Although the flow velocity in the diffuser decreases, a certain proportion of the flow with an increased flow velocity flows into the region immediately behind the diffuser and decreases in its flow velocity only in a downstream region to a flow velocity corresponding to the rest of the flow stream. Along with the increased flow rate of this partial flow, the pressure is lower than at the Ausfädelöffnung, whereby the flushing of the ring line causing negative pressure results at the arranged in this area Einfädelöffnung. However, since the pressure difference is small, preferably acting through the loop to the loop flow resistance under consideration of the ring line configuration, for example by adjusting the surface finish of the ring inner wall, the loop length, the number of Krüm rules or edges should be minimized so to prevent a stop of the loop flow.

In A preferred embodiment of the present invention is the Threaded opening formed in such a way that the recirculated from the loop loop flow under an inflow angle of not more than 75 ° to Main flow direction flows. Preferably the inflow angle between 35 ° and 55 ° to the Main flow direction. Considering the aforementioned inflow angle can a variety of connection fittings in a strand in the flow direction be arranged one behind the other, each for a flow through the Floor or riser string cause a flushing of the loop, without an excessive operating pressure must be spent in the piping system. The flow is thereby with relatively small pressure difference by each individual fitting in the Region of the strand, i. led the mainstream and while returning from the ring line in the strand streamlined and low loss returned. Especially is preferred the inflow angle between 42 ° and 47 ° in the mainstream direction, which stands for a relative to the main flow direction aligned recirculated loop flow results in relatively low pressure loss at the threading.

In a further preferred embodiment of the present invention is the connection fitting according to the invention at least with regard to the configuration of the cross-sectional widening and the entry and exit openings formed symmetrically to at least one center axis of the cross-sectional constriction. In particular, those are a flow leading and a flow cross section training areas of the cross-sectional expansions and the integration and Ausfädelöffnungen symmetrical to, for example, a vertical to the main flow direction Form out the center axis of the cross-sectional constriction, around for both mainstream directions a substantially identical pressure difference between the and Ausfädelöffnung to Generation of a ring line flow to be able to provide.

According to a further preferred embodiment of the present invention, the connection fitting comprises a closure body arranged in the cross-sectional constriction and displaceable in the main flow direction. With the closure body, for example, a flow passage area in the cross-sectional widening can be variably adjusted such that a passage area formed between the closure body and an inner wall of the cross-sectional constriction is enlarged by displacing the closure body in or against the main flow direction or can be reduced. In this way, a pressure difference adapted to different volume flows for generating a loop flow can be achieved in a simple manner.

To a further preferred embodiment of the present invention closes the closure body the cross-sectional constriction at low flow rates up to a critical Volume flow substantially sealing. Below a critical volume flow For the purposes of the present invention, such a volume flow understood that sufficient, the closure body alone due to the closure body acting friction and pressure forces in Main flow direction to move. The aforementioned embodiment has in terms proved to be advantageous in that to be expected, low Pressure difference between inlet and outlet opening when drinking or service water of the completely flowing into the connection fitting volume flow is passed through the loop. Thus, in a simple way Ensures that even in case of insufficient pressure difference between inlet and Ausfädelöffnung to Generation of a ring line flow with removal of drinking or service water a rinsing effect in this and in others to the floor or riser pipe connected ring lines can be achieved.

Preferably is the closure body elliptically educated. This allows one between the closure body and the inner wall of the cross-sectional constriction formed contact surface in the case a tight seal can be increased so on the one hand, the tightness between the closure body and To further improve cross-sectional narrowing and on the other hand the critical volume flow in dependence the between the closure body and the inner wall of the cross-sectional constriction acting frictional force and suitably set the pressure force emanating from the volume flow.

Further Preferably, the closure body acts with at least one in the main flow direction acting return spring together. Thus, the closure body in a simple manner Main flow direction shifted or when the volume flow decreases to its starting position pushed back be, with the between the closure body and the inner wall of the Cross-sectional constriction and cross-sectional enlargement formed passage area dynamic dependent on set the volume flow suitable. In addition, one is for moving the closure body necessary critical volume flow over the amount of spring force of the return spring be provided.

Especially Preferably, a point of application of the return spring is located on the closure body in one parallel to the main flow direction extending symmetry axis of the closure body and preferably acts one from the return spring outgoing force along this symmetry axis. This will become one Tilting of the closure body to be moved encountered, making the closure body lighter be moved in and / or opposite to the main flow direction can.

To a further preferred embodiment of the present invention engages the respective ends in the main flow direction of the closure body at least one return spring at, wherein in the main flow direction acting resulting force of the return spring in flowlessness is equal to zero. The closure body can thus flowless safely held in its starting position. Furthermore, pretension-free and / or prestressed return springs be used. Furthermore, a location of between the closure body and the inner wall of the cross-sectional constriction formed contact surface such chosen be that closer at one or the other cross-sectional widening or evenly spaced lies to these. As a result, in particular one for both main flow directions different from each other specified critical volume flow value be provided. Also, one can reach a the cross-sectional constriction passing throughflow provided Period can be adjusted if necessary.

Further preferred embodiments are through such connection fittings characterized in that receive a pipe parallel to the main flow direction can. This pipe is used to connect the return lines of ring pipes, e.g. the circulation pipe of drinking water warm, train. As well can Drinking water cold ring lines in this way efficient being constructed.

Further Details and advantages of the present invention will become apparent from the following description of two embodiments in conjunction with the drawing. In this show:

1 a longitudinal sectional view of a first embodiment of a connection fitting;

2 a longitudinal sectional view of a second embodiment of a connection fitting with a closure body closing the cross-sectional constriction;

3 and 4 a longitudinal sectional view of the second embodiment of a connection fitting with a deflected in the main flow direction closure body;

5 a longitudinal sectional view of a to the in 1 shown in the first embodiment corresponding third embodiment of a connection fitting with an inner, coaxial tube; and

6 to 8th Longitudinal views of one of the in 2 to 4 shown in the second embodiment corresponding fourth embodiment of a connection fitting with an inner, coaxial tube.

The 1 shows a first embodiment of a connection fitting, which is designed here as a one-piece component via a primary molding process, in particular a molding and casting process. The first embodiment of the connection fitting is symmetrical to a center axis A of a cross-sectional constriction that is vertical to the main flow direction H. 2 the connection fitting formed. The connection fitting has substantially round flow cross-sections. In detail, the connection fitting of the first and second embodiments comprises a central region in which the cross-sectional constriction 2 and two the cross-sectional constriction 2 each end enclosing cross-sectional extensions 3 are provided. The cross-sectional constriction 2 Forms a cylinder section with a flow cross section making up the inner diameter d. The cross-sectional extensions 3 form a cone-shaped cylinder section with a gradually increasing flow cross-section whose diameter D is of the diameter d of the cross-sectional constriction 2 to an inner diameter DN of one of the cross-sectional widening 3 directly adjacent cylinder section 8th increased. The inner diameter DN corresponds approximately to the diameter of the strand, not shown. The cross-sectional constriction 2 forms with cross-sectional extensions 3 thus a venturi, with the one cross-sectional widening 3 as a confuser and the other cross-sectional extension 3 act as a diffuser depending on the main flow direction H. Even if the Venturi nozzle thus formed is shown formed integrally with the connection fitting, the Venturi nozzle can be provided for example in the form of an insert, not shown, which can be inserted into the connection fitting.

In the main flow direction H is acting as a diffuser cross-sectional widening 3 immediately adjacent a Einfädelöffnung 4 intended. To the threading opening 4 leads a threading channel 7 , which is formed obliquely to the main flow direction H. The threading channel 7 closes with the main flow direction H an angle α of about 45 °.

The connection fitting furthermore has a cross-sectional widening acting in the main flow direction H as a confuser 3 upstream Ausfädelöffnung 4 with a Ausfädelkanal 7 on, with the Ausfädelöffnung 4 and the Ausfädelkanal 7 symmetrical to the center axis A with respect to the Einfädelöffnung 4 and the threading channel 7 are formed. Accordingly, a partial flow of the strand flow at an angle β of about 135 ° relative to the main flow direction H in the Ausfädelkanal 7 discharged.

With the particular in 1 shown symmetrical configuration of the first embodiment of a connection fitting, a similar flushing effect of the ring line for each directed in the main flow directions H flow is achieved.

The 2 to 4 show a second embodiment of a connection fitting, wherein like reference numerals identify like components with respect to the first embodiment. The second embodiment differs from the first embodiment essentially in that in the cross-sectional constriction 2 a closure body 5 is provided, at whose respective lying in the main flow direction ends a return spring 6 is arranged. In particular, the shows 2 the closure body 5 in a closed position, ie, in a non-deflected position for a prevailing in the strand volume flow Q, which is smaller than a critical volume flow Q _crit . The critical volume flow Q _crit corresponds in particular to a volume flow value at which the closure body 5 the cross-sectional constriction 2 just closing tightly. As far as a volume flow Q exceeds the critical volume flow Q _crit , the closure body shifts in such a way that a as in the 3 and 4 shown flow passage between the closure body 5 and an inner wall of the cross-sectional constriction 2 and the cross-sectional constriction 3 becomes possible.

The closure body 5 is rotationally elliptical. The main axis of the rotary ellipse lies on a running in the main flow direction H symmetry axis of the cross-sectional constriction 2 along which the closure body 5 is displaceable. The closure body 5 is further arranged such that in its closed position, for example in flowlessness (Q = 0), the minor axis of the rotary ellipse on the center axis A of the cross-sectional constriction 2 lies. The closure body 5 has an inner diameter d of the cross-sectional constriction 2 almost equal maximum diameter, so that the closure body 5 the cross-sectional constriction 2 sealingly closes in its closed position. A running in the main flow direction H diameter of the closure body 5 is essentially freely selectable, specifically, but in such a way that the closure body 5 in the main flow direction H over a region of the cross-sectional constriction 2 in the areas of cross-sectional expansion 3 extends. At the lying in the main flow direction H respective ends of the closure body 5 grab return springs 6 at. The points of attack of the return springs 6 lie in the horizontal axis of rotation of the closure body 5 , The other ends of the return spring 6 are firmly connected to the connection fitting. The fixation of the return springs 6 at the connection fitting is preferably carried out in one of the input and Ausfädelöffnung 4 upstream or downstream, so one in the Ausfädelöffnung 4 leading or one from the threading opening 4 not to impede the coming flow.

With the 3 and 4 becomes a deflection of the closure body 5 the connection fitting according to the invention according to the second embodiment in both main flow directions H shown. The deflection shown can be achieved with a volume flow Q greater than Q _crit , so that a volume flow introduced into the connection fitting is discharged on the one hand into the ring line and on the other hand on the closure body 5 can be passed. The to the closure body 5 attacking return springs 6 experience such a deflection that when the volume flow Q of the closure body 5 is returned accordingly in the direction of its initial position. As return springs 6 Preferably, compression and / or compression springs are used. It is not mandatory at each end of the closure body 5 a return spring 6 but it can be any number of return springs 6 be provided in any arrangement in the connection fitting, as long as the closure body 5 is movable substantially along the main flow direction H from an initial position as the closed position to a deflection position and back again. The shape of the closure body 5 is also not limited to an ellipsoidal shape, but the closure body 5 can also be a parabolic or circular or a different than closure body 5 have suitable cross-section. Also, the diameter of the closure body 5 is customizable according to the circumstances, so that the closure body 5 like in the 2 to 4 shown diameter or a correspondingly smaller diameter.

The first embodiment of a connection fitting is particularly suitable for occurring in the connection fitting constant (stationary) volume flows, while in the 2 to 4 shown second embodiment of a connection fitting in drinking or service water systems with variable (dynamic) volume flows can be used, since here an adjustment of the pressure difference dynamically over in the cross-sectional constriction 2 provided closure body 5 depending on the respective volume flow Q can take place.

The 5 to 8th show a third and fourth embodiment of a connection fitting substantially corresponding to the first and second embodiments, wherein the third and fourth embodiment of the previous one by an inline pipe received from the connection fitting 9 different. Like reference characters indicate like components with respect to the first and second embodiments.

The inliner pipe 9 is coaxial in the main flow direction H and preferably concentric. As in the 6 to 8th shown is the inliner tube 9 from the closure body 5 preferably surrounded such that the liner pipe 9 at the same time one for the closure body 5 in the main flow direction H suitable guide, whereby a tilting of the closure body 5 can be additionally counteracted when moving desselbigen. Furthermore, at the lying in the main flow direction H free ends of the closure body 5 in each case at least three return springs 6 or for example the inliner tube 9 receiving return ring spring (not shown) so attack that one to the liner tube 9 parallel movement of the closure body 5 can be reliably guaranteed. In other words, the springs attack 6 at the free end of the closure body 5 ideally evenly around the inliner tube 9 distributed, with a radial distance of at least 120 ° between adjacent points of attack of the springs 6 on the closure body 5 for a parallel, tilt-free movement of the closure body 5 sufficient.

That in the 5 to 8th shown third and fourth embodiment of a connection fitting shows the same effects and functions shown in connection with the first and second embodiments. In particular, with these Ausführungsbeispie len a ring line for both cold and hot water can be made more efficient, since the liner pipe 9 As a return line for the loop is used, whereby a reliable flushing all connected to the ring and leading to a consumer loops can be achieved.

1

One- and outlet openings

2

Cross-sectional narrowing

3

Cross-sectional widening

4

One- and Ausfädelöffnung

5

closure body

6

return spring

7

One- and Ausfädelkanal

8th

cylinder section

9

liner tube

d

diameter the cross-sectional constriction

D

diameter the cross-sectional widening

DN

diameter of the strand and the cylinder section

H

Main flow direction

Q

flow

Q _crit

critical flow

α

angle between threading channel and mainstream direction

β

angle between Ausfädelkanal and mainstream direction

Claims (15)

Connecting fitting for connecting a ring line with at least one consumer to a floor or riser pipe or ring with connectable to the strand or ring inlet and outlet openings ( 1 ) and intermediate threading and Ausfüelöffnungen ( 4 ) caused by a cross-sectional constriction ( 2 ) are separated from each other, wherein the cross-sectional constriction ( 2 ) of two in the direction of the inlet and outlet ( 1 ) gradually widening cross-sectional extensions ( 3 ); characterized in that the threading opening ( 4 ) in the area of a cross-sectional extension ( 3 ) and / or immediately at this on the cross-sectional constriction ( 2 ) is disposed adjacent to the opposite side; and that the Ausfädelöffnung ( 4 ) in the area of the other cross-sectional extension ( 3 ) and / or at this on the cross-sectional constriction ( 2 ) opposite side is located immediately adjacent. Connection fitting according to claim 1, characterized in that the threading opening ( 4 ) is formed such that the recirculated ring loop flow from the ring line at an inflow angle (α) of not more than 75 degrees to the main flow direction (H) flows. Connection fitting according to claim 2, characterized that the inflow angle (α) between 35 degrees and 55 degrees to the main flow direction (H) is. Connecting fitting according to claim 2 or 3, characterized characterized in that the inflow angle (α) between 42 degrees and 47 degrees to the main flow direction (H) is. Connection fitting according to one of the preceding claims, characterized in that the connection fitting at least with regard to the configuration of the cross-sectional extensions ( 3 ) and the entry and Ausfüelöffnungen ( 4 ) symmetrical to at least one center axis (A) of the cross-sectional constriction ( 2 ) is trained. Connection fitting according to one of the preceding claims, characterized in that the connection fitting a in the cross-sectional constriction ( 2 ) and in the main flow direction (H) slidable closure body ( 5 ). Connection fitting according to claim 6, characterized in that the closure body ( 5 ) the cross-sectional constriction ( 2 ) at a small volume flows (Q) to a critical volume flow (Q _crit ) substantially sealingly closes. Connection fitting according to claim 6 or 7, characterized in that the closure body ( 5 ) is elliptical. Connecting fitting according to one of claims 6 to 8, characterized in that the closure body ( 5 ) with at least one in the main flow direction (H) acting return spring ( 6 ) cooperates. Connecting fitting according to claim 9, characterized in that a force application point of the return spring ( 6 ) on the closure body ( 5 ) in a direction parallel to the main flow direction (H) extending symmetry axis of the closure body ( 5 ) and that of the return spring ( 6 ) outgoing force acts along the axis of symmetry. Connecting fitting according to claim 9 or 10, characterized in that at the respective in the main flow direction (H) lying ends of the closure body ( 5 ) at least one return spring ( 6 ) acting in the main flow direction (H) acting force is zero in flowlessness. Connection fitting according to one of the preceding claims, characterized characterized in that the connection fitting is cast as one piece Component is formed. Connection fitting according to one of the preceding claims, characterized in that the connection fitting has a pipe arranged in parallel in the main flow direction (H) ( 9 ). Connection fitting according to claim 13, since characterized in that the pipe ( 9 ) is arranged coaxially in the main flow direction (H). Drinking and process water system with at least one Floor or riser pipe or ring, characterized by several in the flow direction in the strand or ring successively arranged ring lines, leading to at least one consumer and one each Connection fitting according to at least one of the preceding claims to the Strand are connected.