EP3263781A1 - Inlet fitting - Google Patents

Abstract

An inlet fitting (1) for filling a flushing cistern comprises a housing (2), a water guide channel (3) arranged in the housing (2) with an inlet (4) and an outlet (5), a float-controlled valve arranged in the water guide channel (3) (6), which blocks the water supply channel (3) or releases during filling, and a float (7) cooperating with the valve (6) for controlling the valve (6), the float (7) being filled with water Cavity (8) and at least one buoyancy chamber (9). Furthermore, the inlet fitting (1) comprises an additional water tap (10) branched off from the water guide channel (3) for filling said cavity (8) to provide an additional weight. In the water guide channel (3) at least one backwater element (11) is arranged in the region of the additional water tap (10), with which a backwater in the region of the additional water tap (10) for pressure-independent removal of additional water is provided.

Description

TECHNICAL AREA

The present invention relates to an inlet fitting for a cistern according to the preamble of claim 1.

STATE OF THE ART

Inlet fittings are used for filling cisterns of sanitary items, such as toilets or urinals. The filling should be done in a relatively short period of time, so that the flushing is quickly operational again. For example, is from the EP 1 292 736 an inlet fitting has become known.

PRESENTATION OF THE INVENTION

Based on this prior art, the invention has a preferred object to provide an inlet fitting, which optimizes the tap of additional water, which is diverted separately from the actual rinse water from the inlet fitting. In particular, it is an object of the invention to provide an inlet fitting, the diversion of the additional water is independent of the water pressure in the inlet fitting.

Accordingly, an inlet fitting for the filling of a cistern comprises a housing, a housing arranged in the water supply channel with an input and an output, a arranged in the water guide channel float-controlled valve, which Water supply channel locks or releases when filling the cistern, and a cooperating with the valve float to control the valve, wherein the float has a water-fillable cavity and at least one buoyancy chamber. The inlet fitting further comprises a branched off from the water supply duct additional water tap for filling said cavity to provide additional weight on the float, and at least one in the water supply channel, in particular in the region of Zusatzwasserabgriffs, arranged backwater, with which a backwater in the region of Zusatzwasserabgriffs for pressure-independent removal of additional water is available.

The arrangement of the back pressure element, which can also be referred to as a throttle element, ensures at different pressure conditions that always a substantially equal amount of make-up water can be diverted from the inlet fitting regardless of the pressure conditions prevailing in the water duct.

Due to the constant tapping of additional water regardless of the water pressure, in particular closing accuracy of the inlet fitting can be increased because the cavity is always filled with the substantially same amount of water, which is independent of the pressure.

The additional water tap is preferably designed such that it is led away from the water guide channel and is directed to the said cavity of the float. Typically, the auxiliary water tap is a small water channel with a cross-section that is many times smaller than the cross-section of the water guide channel.

When installed, the inlet communicates with a water supply line and the outlet protrudes into the interior of a flushing cistern.

Preferably, the backflow element is designed such that the cross section of the back pressure element is increased with increasing pressure. The magnification is included in such a way that the quantity of water supplied to the additional water tap, in particular over a pressure range of 0.1 to 10 bar, is essentially constant.

Particularly preferably, the backflow increases the cross section of the water supply channel with increasing pressure such that a larger amount of water flows through the outlet and that the amount of water via the additional water tap is preferably constant.

Due to its design, the backwater element ensures that a uniform tapping of make-up water is possible. In this case, a higher amount of water is supplied at the output with increasing pressure.

Preferably, the backwater is deformed at increasing pressure and the deformation of the cross-section of the backwater is increased. This means that the cross section of the backwater element changes with changing pressure conditions.

The backflow element preferably extends over the entire cross section of the water guide channel, so that the cross section of the water guide channel in the region of the backflow element essentially depends on the degree of opening of the backflow element.

Particularly preferably, the backflow element is designed like a disk. The disc-like backflow element is preferably transverse to the water supply channel in the same. The additional water tap is preferably arranged directly in the region of the disk surface with respect to a direction orthogonal to the disk surface. Alternatively, the additional water tap is arranged at a small distance from the backwater element. By a small distance is meant a distance of a few centimeters. In a further alternative, the backflow element is arranged at a greater distance to the additional water tap.

The backflow element is preferably arranged in the direction of flow of the water in the water guide channel after the additional water tap.

Preferably, the backwater element is made of a resilient material, in particular of a resilient plastic or rubber or silicone. Such materials have proven to be advantageous in the deformation with increasing pressure and in the return deformation at falling pressure again.

The backflow element particularly preferably has a Shore hardness of greater than 50 Shore or greater than 60 Shore or greater than 70 Shore. Lower values are also conceivable.

Preferably, the backflow element has a plurality of cuts, which subdivide subregions of the backflow element into lobes. The lobes can be folded down in the direction of flow by the water pressure with respect to the water guide channel. This means that as the water pressure increases, the lobes move in the direction of flow, increasing the cross-section of the backwater element.

Preferably, said cuts extend radially outward from a central opening. Particularly preferably, three or more than three incisions are arranged.

Preferably, the backwater element is arranged in the water guide channel and is mounted in a side surrounding the water supply channel bearing. The bearing is preferably formed as an annular gap in which the backwater is firmly clamped. It is therefore a positive and non-positive connection. Other connection types are also possible.

Preferably, the inlet fitting comprises an outlet pipe, which provides parts of the water guide channel and the outlet, through which the rinse water can be discharged into a cistern, wherein the backflow element is located in the flow direction in front of the outlet pipe. Alternatively, as seen in the flow direction, the backflow element lies in the region of the inlet into the outlet pipe, ie in particular there, from where the pipe extends downwards from the housing. The inlet fitting is formed with the housing and the outlet tube substantially in two parts.

The outlet tube is attached to the housing, wherein the additional water tap is preferably a part of the housing.

Particularly preferably, the backflow element is clamped between outlet pipe and housing. In particular, then the backwater element acts as a seal between the outlet pipe and the housing. The sealing effect is such that no water can escape from the water guide channel through the connection point between the housing and the outlet pipe.

Preferably, the cross section of the water guide channel runs conically in the direction of flow after the backflow element, wherein the taper is preferably such that the cross section of the water guide channel decreases with increasing distance from the backflow element. The conicity with the step has the advantage that it can come to a full filling tube.

Particularly preferably, the cross section increases again after reaching a step at the end of the conicity.

Preferably, the water supply channel, as seen from the inlet, comprises a nozzle with a nozzle channel.

The float preferably acts on the float controlled valve via a float lever. The float is preferably connected via a rod or spindle with the float lever, wherein the rod or the spindle is oriented at right angles to the water surface. The float is preferably attachable to the rod or spindle at different positions.

An arrangement comprises a cistern and an inlet fitting according to the above description. The inlet fitting is arranged in the cistern and communicates with a supply line.

Further embodiments are given in the dependent claims.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1

eine perspektivische Ansicht einer Einlaufgarnitur nach einer Ausführungsform der vorliegenden Erfindung;

Fig. 2

eine Schnittansicht der Einlaufgarnitur nach Fig. 1; und

Fig. 3

eine weitere Schnittansicht der Einlaufgarnitur nach Fig. 1.

Preferred embodiments of the invention will be described below with reference to the drawings, which are given by way of illustration only and are not to be interpreted as limiting. In the drawings show:

Fig. 1

a perspective view of an inlet fitting according to an embodiment of the present invention;

Fig. 2

a sectional view of the inlet fitting according to Fig. 1 ; and

Fig. 3

a further sectional view of the inlet fitting after Fig. 1 ,

DESCRIPTION OF PREFERRED EMBODIMENTS

In the FIGS. 1 to 3 an inlet fitting 1 according to an embodiment of the present invention for the filling of a cistern is shown.

The inlet fitting 1 comprises a housing 2, a water guide channel 3 arranged in the housing 2 with an inlet 4 and an outlet 5, a float-controlled valve 6 arranged in the water guide channel 3 and a float 7 cooperating with the valve 6. The float-controlled valve 6, which is arranged in the Figures 2 and 3 is shown, locks the water channel 3 and releases it during the filling of the cistern. The float 7 is used to control the valve 6. The float 7 has a water-filled cavity 8 and at least one buoyancy chamber 9. The buoyancy chamber 9 is designed to be open at the bottom and is airtight at the top, so that when filling air in the buoyancy chamber 9 includes, so that the float 7 undergoes a buoyancy. Buoyancy chamber 9 and the volume of the cavity 8 are chosen such that at full filling of the cavity 8 of the float has a buoyancy, which is matched as well as possible to the valve 6.

Furthermore, the inlet fitting 1 comprises a branched off from the water channel 3 Zusatzwasserabgriff 10. With the additional water tap 10, the cavity 8 can be filled at the float 7. That is, with open valve 6 is not only on the Output 5 water delivered, but also on the additional water tap 10. The tapped via the additional water tap 10 water is passed into said cavity 8. For this purpose, the additional water tap 10 an outlet 22, which is directed to the cavity 8. The additional water flows along the dashed line W. The additional water tap 10 is provided in the figures shown by a passage 23 from the water supply channel 3 in the direction of outlet 22. The additional water content is approximately 2 to 5% of the total water content that flows through the water supply channel.

In the embodiment shown, an optional control bore 26 is also present, which also supplies water to the cavity 8. However, flows through the control bore 26 only a very small proportion of water. This proportion is less than 1% of the total water that flows through the water channel.

When the valve 6 is open, the water flows out of the inlet fitting both via the outlet 5 and via the additional water tap 10.

Furthermore, at least one backflow element 11 is arranged in the water guide channel 3, in particular in the region of the additional water tap 10. With the backwater 11 is a backwater of water flowing in the water channel 3 in the area of Zusatzwasserabgriffs 10 for pressure-independent removal of additional water available. Under a pressure-independent extraction of make-up water is understood that independently or not depending on the water pressure in the water supply channel 3, a constant amount of make-up water can be passed through the additional water tap 10 to the cavity 8. That is, the amount of make-up water is independent or detached from the ruling in the water supply duct 3 pressure conditions.

The backflow element 11 is preferably designed such that the cross section Q of the backflow element 11 is increased with increasing pressure in the water supply channel 3. The increase is such that the additional water tap 10 supplied amount of water is substantially constant. Particularly preferably, the backflow element is designed such that it emits a constant amount of water over the additional water tap 10 over a pressure range of 0.1 to 10 bar. With sinking water pressure The cross-section Q of the backflow element 11 then decreases again, so that with decreasing pressure a constant amount of water can be removed from the water supply channel 3 via the additional water tap 10.

The backflow element 11 is deformed with increasing pressure, whereby the deformation of the said cross section of the water guide channel 3 increases in the region of the backflow element 11. Likewise, the cross section of the water guide channel 3 decreases in lowering pressure, whereby the cross section is then also reduced.

The backflow element 11 is formed in the embodiment shown as a disk or disc-like. The disk extends substantially over the entire cross section of the water guide channel. 3

The additional water tap 10 is arranged substantially directly in the area of the disk surface 12 with respect to a direction R that is orthogonal to the disk surface 12. Another arrangement is also conceivable. Thus, it would be conceivable that the additional water tap 10 is arranged at a small distance from the backflow element 11. The distance can also be greater.

The backflow element 11 is arranged in the embodiment shown in the flow direction F of the water in the water guide channel 3 after the additional water tap 10. This means that the water first passes through the additional water tap 10 and then impinges on the backflow element 11. In the embodiment shown, the backflow is formed in the back pressure zone by the reference Z. By this backwater in this zone, the additional water tap 10 can be efficiently supplied with the additional water.

The back pressure element 11 is preferably made of a resilient material, in particular of a resilient plastic, or made of rubber or silicone. Preferably, the backwater element has a Shore hardness of greater than 50 Shore, or greater than 60 Shore or greater than 70 Shore.

In the embodiment shown, the backflow element 11 has a plurality of cuts 13 on. The incisions 13 extend radially outward from the center of the backflow element 11 and subdivide the subregions of the backflow element into lobes 14. The flaps 14 can then be folded down in the flow direction F by the water pressure with respect to the water guide channel. That is, the backwater element 11 is deformed by folding the flaps 14. The incisions 13 extend in the embodiment shown by a central opening 15 radially outward.

The backflow element 11 is mounted in the water supply channel 3 in a water guide channel 3 laterally surrounding bearing 16. The bearing 16 is formed as an annular gap and receives the edge region of the backwater element 11 accordingly.

In the illustrated embodiment, the inlet fitting 1 comprises an outlet pipe 17. The outlet pipe 17 thereby provides parts of the water guide channel 3 and the outlet 5. Through the outlet pipe 17, rinse water can be released into the cistern. The backflow element 11 is arranged in the flow direction F in front of the outlet pipe 17. Preferably, the housing 2 and the outlet tube 17 form two different parts. That is, the outlet pipe 17 is fixed to the housing 2. Between the outlet pipe 17 and the housing 2, the backflow element 11 is clamped in the embodiment shown. Preferably, the outlet tube is connected to the housing via a threaded connection 18. Alternatively, a snap connection may be provided.

In the embodiment shown, the cross section of the water guide channel 3 seen in the direction of flow F extends conically after the backflow element 11. The conicity is preferably such that the cross section of the water guide channel 3 decreases with increasing distance from the backwater 11. The conical section ends with a step 19. Then, the cross section of the water guide channel 3 increases again with increasing distance from the step 19.

In the embodiment shown, the float is mounted with an opening 24 on the outlet pipe 17 on the outside movable. The float 17 communicates with a rod 21 which acts on a float lever 20. The float lever 20 acts on the valve 6.

In the illustrated embodiment, the water is passed past an inlet 4 ago at an optional nozzle 25 and then flows to the valve 6 from where the water then flows in the direction of the backflow element 11. LIST OF REFERENCE NUMBERS 1 inlet fitting 26 control bore 2 casing W additional water 3 Water duct F flow direction 4 entrance Q cross-section 5 output R direction 6 Valve Z Zone of backwater 7 swimmer 8th cavity 9 buoyancy chamber 10 Zusatzwasserabgriff 11 backwater element 12 disk surface 13 cuts 14 cloth 15 central opening 16 depository 17 outlet pipe 18 threaded connection 19 step 20 float lever 21 pole 22 outlet 23 passage 24 opening 25 jet

Claims (15)

Includes inlet fitting (1) for filling a cistern
a housing (2),
a water supply channel (3) arranged in the housing (2) with an inlet (4) and an outlet (5),
a in the water supply channel (3) arranged float controlled valve (6), which blocks the water supply channel (3) and releases during the filling, and
a float (7) cooperating with the valve (6) for controlling the valve (6), the float (7) having a water-fillable cavity (8) and at least one buoyancy chamber (9), characterized in that
the inlet fitting (1) further comprises an auxiliary water tap (10) branched off from the water guide channel (3) for filling said cavity (8) to provide an additional weight to the float (7), and
that in the water supply channel (3), in particular in the region of the additional water tap (10), at least one backflow element (11) is arranged, with which a backwater in the region of the additional water tap (10) for pressure-independent extraction of additional water is provided. Inlet fitting (1) according to claim 1, characterized in that the backflow element (11) is designed such that the cross section (Q) of the backflow element (11) is enlarged with increasing pressure, such that the additional water tap (10) supplied amount of water, in particular over a pressure range of 0.1 to 10 bar, is substantially constant. Inlet fitting (1) according to one of the preceding claims, characterized in that the backflow element (11) is deformed at increasing pressure and is enlarged by the deformation of the cross section of the water guide channel (3) in the region of the backflow element (11). Inlet fitting (1) according to any one of the preceding claims, characterized in that the backwater element (11) is disk-like and that the additional water tap (10) preferably extends directly in the region of the disk surface (12) with respect to a direction orthogonal to the disk surface (12) ) or preferably only at a small distance from the backwater element (11) is arranged. Inlet fitting (1) according to one of the preceding claims, characterized in that the backflow element (11) in the flow direction (F) of the water in the water guide channel (3) after the additional water tap (10) is arranged. Inlet fitting (1) according to one of the preceding claims, characterized in that the backpressure element (11) of a resilient material, in particular of a resilient plastic or of rubber or silicone. Inlet fitting (1) according to one of the preceding claims, characterized in that the backflow element has a Shore hardness of greater than 50 Shore. Inlet fitting (1) according to one of the preceding claims, characterized in that the backflow element (11) has a plurality of cuts (13) which divide subregions of the backflow element into lobes (14), which lobes (14) are affected by the water pressure with respect to the water guide channel (3 ) in the direction of flow (F) are hinged. Inlet fitting (1) according to claim 8, characterized in that the notches (13) extend radially outward from a central opening (15). Is mounted fill valve assembly (1) according to one of the preceding claims, characterized in that the backpressure element (11) laterally surrounding the water passage (3) in a water guide channel (3) bearing (16). Inlet fitting (1) according to one of the preceding claims, characterized in that the inlet fitting (1) comprises a part of the water guide channel (3) and outlet pipe (17) which provides the outlet (5), through which the rinse water can be dispensed into a cistern, the backwater element (11) facing in front of or in the region of the inlet into the outlet pipe (17). Inlet fitting (1) according to claim 11, characterized in that between outlet pipe (17) and housing (2) the backflow element (11) is clamped. Inlet fitting (1) according to claim 12, characterized in that the backflow element (11) acts as a seal between the outlet pipe (17) and the housing (18), such that no water from the water guide channel (3) through the connection point between housing ( 2) and outlet pipe (17) can escape. Inlet fitting (1) according to one of the preceding claims, characterized in that the cross section of the water guide channel (3) in the flow direction (F) after the backflow element (11) is conical, wherein the conicity is preferably such that the cross section of the water guide channel ( 3) decreases with increasing distance from the backflow element (11). Inlet fitting (1) according to claim 14, characterized in that the cross section increases again after reaching a step (19) at the end of the conicity.

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