EP0151998A2 - Water aerator for sanitary fittings and the like - Google Patents

Abstract

The invention relates to a water jet aerator which, in place of conventional metal screens, has at least two separate staircase-like obstacles, which project laterally into the paths of the individual jets and split up the jets, and mix them with air. Several such obstacles are arranged in the immediate proximity of one another, successively in the direction of flow, so that a cohesive, well-ventilated jet is obtained. The configuration of the jet cross-section can vary as a function of the arrangement of the facing walls defining the flow path in the area of the obstacles.

Description

The invention relates to a water jet aerator for sanitary fittings and the like with at least one device for generating individual jets, at least one chamber underneath for air access and at least one device for separating and mixing the individual jets with air.

Such devices are widely used today because a ventilated water jet does not spray and allows low-noise inflow of water, and because z. For example, when washing hands, the amount of water can be reduced without this having an adverse effect on the handling of the aerated jet.

The device for generating individual jets is essentially of a uniform design in the individual known water jet aerators. For this are a or several perforated plates arranged one above the other are provided, the holes being normally offset from one another. Underneath the bottom perforated plate there is usually a free space with the possibility of outside air so that air can be drawn in here. There are significant differences in the known jet aerators in the way the individual jets are broken down. For this purpose, in many common jet aerators, a screen arrangement of several finely divided screens arranged one above the other is provided, by means of which the jet is broken down and the mixing with air is effected. However, these jet aerators tend to become blocked by calcification. A jet aerator is known from German patent specification 21 14 618, in which the individual jets strike oblique surfaces of a mushroom-like impact body and are thereby broken up and mixed with the air. However, the mushroom-like body takes up a large part of the flow cross-section, whereby a strong braking of the water jets and also an unfavorable cross-sectional ratio is achieved. This is even clearer with the jet aerator according to German Offenlegungsschrift 28 21 195, in which the individual jets are directed onto baffle plates which reflect the jets. A shower head is known from European patent application 82102033 (60540), with the aid of which a large number of individually aerated shower jets can be formed. For this purpose, free through channels are provided, the inner walls of which have obstacles for dividing and splitting the individual beams. The ventilated jets emerging from these channels have a relatively small cross section. They are suitable for a shower or shower head, but less so for the outlet of a mixing valve, one Bathtub spout or the like.

The invention is therefore based on the object to provide a water jet aerator, in particular for taps and inlets for bathtubs, which enables the formation of a uniformly ventilated full jet without the risk of calcification, as is the case with water jet aerators with sieves.

The invention consists in that at least two devices for the decomposition of individual beams are provided, which have mutually cooperating walls capturing the individual beams, at least one of which has obstacles projecting laterally into the path of the individual beams, and in that at least one device for decomposing the individual beams in essentially only two mutually opposing interacting walls are provided and at least two devices for the decomposition of individual jets are so close together that the aerated jets emerge as jointly aerated steel.

It has been found that the generation of aerated jets with a sufficiently large cross-section for a normal tap or the inlet for a bathtub is possible in that instead of channels with a substantially circular cross-section, as described in European patent application 82102033 , Channels or the like can be used, which are only limited from two sides. A minimal deflection of the individual beams is sufficient, as is the case with the subject of European patent application 82102033, to which reference is made here. That means that it is enough in the path of the individual beams or a part of which to provide lateral obstacles, the lateral extent of which is in the order of the diameter of the individual beams. Additional cross-sectional constrictions are not necessary. Jet separation screens are also not provided. It is even an advantage of the invention that the water jet aerator is free of such screens. Rather, the through

channel or the further path of the rays remain essentially the same in cross-section after their decomposition. In this way, line or. Strip-shaped aerated jets are obtained which can be kept as long as desired in cross-section in their cross-section, whereas the thickness or width can be determined by the distance between the interacting walls and adjusted to an optimum. Through a close juxtaposition of such strips, full jets with a larger cross section can be obtained, which have a good radiance, since the individual jets are only slightly deflected from their original direction when they are broken down. The strips are preferably ring-shaped and arranged concentrically to one another.

As a rule, a plurality of ring-shaped devices for the separation and ventilation of the individual jets are arranged concentrically to one another, wherein the innermost device can also be arranged in a ring around a core or can consist of a separation and ventilation device with a free central through-channel. A common device for generating individual jets and an associated air chamber are preferably assigned to several, in particular all, devices for decomposing and ventilating the individual jets.

The interacting walls of the devices for the decomposition and ventilation of the individual jets are preferably continued down to the outlet opening of the aerated jets, around the aerated ones Calm rays. In addition, partition walls extending essentially perpendicular to these walls in the jet direction can also be provided, preferably at the lower outlet opening of the jet aerator. Steps in the form of steps are particularly suitable as obstacles to the splitting of the individual jets, the individual steps, viewed in the direction of flow of the individual jets, projecting increasingly further into the passage space of the devices for splitting the individual jets. The opposite wall is preferably set back in a corresponding manner so that the through-channel between the walls does not experience any significant narrowing. As a rule, such a stair-shaped obstacle has two to eight, preferably two to four steps. The number of individual beams that are directed at least partially towards the stair-shaped obstacles can be varied within wide limits. In the case of concentrically arranged staircase-shaped obstacles, the outlet openings preferably also lie on concentric rings. One or more rows or rings of openings for the formation of individual jets can be directed towards a device for the separation and ventilation of individual jets. However, a row or a ring with openings for the formation of individual beams can also be directed at two devices for the decomposition of individual beams, in particular when these devices are designed as two-sided stairs with a common top step. As a rule, it is sufficient if one of the mutually interacting walls has obstacles in the devices for the decomposition of the individual beams. The opposite wall then holds the jet apart and mixed with the air. However, such obstacles can be provided on the two opposite sides of the walls, preferably in height are offset from each other. The walls can interact with other walls on both sides and can be equipped with obstacles on both sides. In the case of concentrically arranged dismantling devices, at least the inner wall is preferably provided with obstacles. If the obstacles are double-sided, in particular in cross-section in the manner of a step pyramid, then the obstacle directed towards the center preferably has less or less wide or deep steps. As a result, the passage between the opposing obstacles or walls can be kept as wide as possible, which is also supported by the fact that the mutually facing obstacles are at least partially preferably completely offset from one another in the axial direction. The smallest distance between two opposite walls in the area of the obstacles, ie the smallest distance that the beams have to pass since they left their exit openings in the perforated plate, can thus advantageously be in the range of 0.5 to 1.5 times, preferably 0 , 7 to 1.2 times the further spacing of the partition walls. The further course of the aerated jets takes place after the separation device between the preferably parallel walls, essentially without changing the cross-section, up to the exit surface, as a result of which a good jet pattern is obtained. Since the partitions between the individual strip-shaped or ring-shaped outlet openings for the ventilated jets are kept thin, preferably have a cutting shape towards the outlet opening, these jets are combined without disturbing the jet pattern. A much more uniform and better ventilated steel is thus obtained than is the case when an attempt is made to extend a ventilated jet of small cross-section to such a larger cross-section. Further features and details of the invention emerge from the following description of embodiments in conjunction with the drawing and the claims.

• Fig. 1 ein Schnitt durch eine Ausführungsform nach der Erfindung in montiertem Zustand
• Fig. 2 eine Draufsicht auf die Ausführungsform nach Fig. 1 in unmontiertem Zustand, wobei die Einrichtung zur Erzeugung von Einzelstrahlen teilweise weggelassen ist,
• Fig. 3 ein Schnitt durch eine andere Ausführungsform der Erfindung in montiertem Zustand
• Fig. 4 eine Draufsicht auf die Ausführungsform nach Fig. 3, in unmontiertem Zustand, wobei die Einrichtung zur Erzeugung von Einzelstrahlen teilweise weggelassen ist,
• Fig. 5 eire Teiluntenansicht einer weiteren Ausführungsform,
• Fig. 6 einen Schnitt durch die Ausführungsform nach Fig. 5 in montiertem Zustand,
• Fig. 7 eine Draufsicht auf die Ausführungsform nach Fig. 5, wobei ein Teil der Einrichtung zur Erzeugung von Einzelstrahlen teilweise weggelassen ist.

The drawing shows:

• Fig. 1 shows a section through an embodiment according to the invention in the assembled state
• 2 shows a plan view of the embodiment according to FIG. 1 in the unmounted state, the device for generating individual beams being partially omitted,
• Fig. 3 shows a section through another embodiment of the invention in the assembled state
• 4 shows a plan view of the embodiment according to FIG. 3, in the unmounted state, the device for generating individual beams being partially omitted,
• 5 shows a partial bottom view of a further embodiment,
• 6 shows a section through the embodiment according to FIG. 5 in the assembled state,
• Fig. 7 is a plan view of the embodiment of FIG. 5, with part of the device for generating individual beams is partially omitted.

In the embodiments of the invention shown in FIGS. 1 to 7, a substantially cylindrical water jet aerator 1 is provided, which in the usual way with a sleeve 4 having an external thread 2 and an abutment shoulder 3 with the interposition of a sealing ring 5 at the outlet opening of a tap 6 or the like is attached.

The aerator 1 is made up of essentially four functional units when viewed in the direction of flow, namely a device 7 for generating individual water jets, which is created from two perforated plates 8 and 9 with mutually offset holes, an air space 10 located underneath, which also has lateral openings 11 Air is supplied, and a plurality of concentric stair-shaped devices 12 for decomposing the individual jets with simultaneous mixing with air, to which are connected concentric guide channels 13, which serve to calm and stabilize the water / air mixture. The guide channels have common partitions 14 and additional radial partitions 15, which are kept so thin at least on the outlet side that the air / water streams unite when they emerge from the aerator 1 to form a single common aerated water jet. The dividing walls 14 and 15 extend down to the exit surface of the aerated jet, the concentric dividing walls 14 representing the continuation of the bottom step 16 of the step-shaped obstacles 12 downward and the radial dividing walls 15 only beginning below the obstacles 12 and cutting edge-like downwards rejuvenate. The jet aerator 1 has an outer jacket 17 with the usual outer diameter and with a step-like widening in the upper region, which serves to abut the shoulder 3 of the fastening sleeve 4.

In the embodiment according to FIGS. 1 and 2, four concentrically arranged cylindrical sleeves 14 and 17 are provided, which end in a common exit plane for the ventilated jet and delimit four through channels 18, 19, 20 and 21, the channel lying in the center 18 are cylindrical and the channels 19 to 21 arranged around them are formed as ring channels, which are interrupted by eight web-like radial partition walls 15. The outermost sleeve forms the outer jacket 17 of the jet aerator 1.

The sleeves representing the concentric partitions 14 are increasingly longer from the inside to the outside and meet at their upper end ring-shaped attachments 22, 23 and 24, which are designed in the manner of step pyramids in cross-section, that is to say step-like on both sides. The inner cap 22 of the inner partition 14 around the channel 18 has only one step 25 on both sides, which is narrow and high and is designed to reduce the wall thickness of the partition. In contrast, the attachments 23 and 24 of the outwardly adjoining - partitions 14, which delimit the channels 19 and 20 from the outside and the channels 20 and 21 from the inside, have two-step stairs on both sides, in which the step depth is also smaller than the step height, whereby the depth of the step on the inside of the attachment 24 is also even smaller than on the outside. In addition, the attachments 23 and 24 rest asymmetrically on the associated partitions 14, which represent an extension of the bottom outer step 16 downwards, whereas the rest of the inwardly facing part of the attachments 23 and 24 is self-supporting in the manner of an undercut. This results in a preferably outwardly diverging division of the individual beams. Furthermore, the tops 22 to 24 are offset in height so that the lower edge of the bottom step of an outer staircase is at least as high as the top edge of the top step of the next inner staircase. As a result of this axial, funnel-shaped offset, the stair-shaped attachments 22 to 24, which bring about the splitting of the individual beams, can be arranged at short radial distances from one another, which in projection is only about the width of one
Level correspond without the flow cross-section for the air / water mixture between the essays is affected. This enables a close arrangement of jet separation obstacles 12 with respect to the cross section of the jet aerator, which results in the formation of a well-ventilated full jet over the entire cross section of the aerator.

The upper perforated plate 8 has a large central hole 26 which is adjusted by the lower perforated plate 9. Through a space 27 between the two plates 8 and 9, the water can spread evenly over the lower plate 9. This has four concentric annular rows of holes 28, 29, 30 and 31, each having ten holes. The holes from the inner row of holes 28 to the outer row of holes 31 become increasingly larger, and their rows overlap each other so that each step of the attachments 23 and 24 is struck by individual jets and the outer attachment 24 in accordance with the larger flow cross section of the flow channels 20. and 21 more water is supplied than the channels 18 and 19. In addition, the outer jacket 17 in this embodiment has no stair-like obstacles, so that the channel 21 only from a stair-shaped obstacle, namely from the outside of the stair-shaped attachment 24 with water / Air mixture is supplied. This is compensated for by the larger holes in the outer row of holes 31. Furthermore, the rows of holes 28 to 31 are arranged in the perforated plate 9 such that the inner stair-shaped attachment 22 which surrounds the cylindrical channel 18 and the inside of the first annular channel 19 is not directly struck by the individual jets emerging from the holes of the rows of holes 28 to 31, but from rays that are mainly deflected from the inside of the next outer stair-shaped obstacle 23 and be further dismantled on both sides of the obstacle 22.

The water jet aerator according to the invention can be manufactured completely from plastic in a simple manner, the body of the aerator which has been freed from the two perforated plates 8 and 9 and which has the air inlet openings 11, the jet separation devices 12 and the guide channels 13, can be produced in one piece in a simple manner by injection molding is without the need for complicated molds. In addition, the structural design of the jet aerator according to the invention enables numerous variations without having to depart from the mode of operation. In this way, a plurality of annular channels with the associated jet splitting devices can be additionally provided, increasing the overall cross section of the aerated jet. In order to enable a low overall height, additional beam separation obstacles can in turn be provided at a low level, starting with one another in an ascending arrangement. It is also possible to deviate from the circular shape so that the ring channels have an oval or correspondingly different cross section, and the center of the aerator can also be filled or have an independent air supply, so that an annular aerator jet results. A star-shaped, in particular radial, arrangement of the obstacles is also possible.

In the embodiment according to FIGS. 3 and 4, the same reference numerals are used for the same parts as in the embodiment according to FIGS. 1 and 2. For this reason, these parts are not described again separately. In the embodiment according to FIGS. 3 and 4, four channels 13 are provided, all of which are designed as ring channels. Instead of the cylindrical channel 18 of the embodiment according to FIG. 1 here the center 32 is of solid construction and itself has a stair-like attachment 33 with an annular step. However, several stages could also be provided. However, the diameter of the solid center is kept so small that the annular aerated jets emerging from the channels 13 unite to form a common full jet, especially since the center 32 is not aerated. The subsequent stair-like attachments 34, 35 and 36 of the concentric partition walls 14 have fewer steps on their inside than on the outside. This makes it possible to keep the height difference between the essays smaller, so that they overlap in height. At the same time, there is the possibility of moving the attachments closer together in the radial direction and thus reducing the channel width without the flow cross-section between the attachments becoming smaller. This is illustrated in the relationship of the attachments 35 and 36 to one another, the attachment 36 not being stepped on the inside.

In this embodiment, two perforated plates 37 and 38 with gaps 39 are arranged one above the other in order to generate the individual jets, the holes between the two plates being at least partially offset from one another, which is known per se. Four rows of holes 40 to 43 are again provided, this time the diameter of the holes being the same, but the number of holes per row of holes increasing from the inside to the outside. The holes of the outer rows of holes 41 to 43 do not overlap each other and are each directed towards the outer stepped gradations of the attachments 34, 35 and 36. In contrast, the innermost row of holes 40 is mutually overlapping to the row of holes 41 arranges and meets, as can be seen from the right half of FIG. 3 (the section deviates from the plane, similar to that in FIG. 1), directly to the uppermost step 44 and the inwardly following lower step 45 of the stair-shaped attachment 34 .

In the embodiments according to FIGS. 1 to 4, the stepped gradation of the disassembly devices 12 or the stair-like attachments, which is emphasized to the outside, tends to deflect the individual jets emerging from the lower perforated plate 9 or 38 more towards the outside than towards the inside. As a result, the outlet cross section of the jet aerator for the air / water mixture can be used to the maximum, so that the entire inlet cross section for the individual water jets can also be kept correspondingly large. Conversely, in special cases it may be desirable to keep the outflow cross-section of the aerated jet relatively small without the connection dimensions of the ventilation device and the external appearance being changed thereby.

This is the case in the embodiment according to FIGS. 5 to 7. Here, as can be seen in particular from FIG. 6, two concentric sleeves 46 and 47 are provided which are essentially cylindrical in the lower region and widen in a funnel shape in the upper region. In the respective upper area, the sleeves have a step-shaped step 48 on the inside, each with four individual steps. The inner sleeve 46 is even stepped on the outside of the funnel-shaped area. The funnel-shaped areas of the two sleeves 46 and 47 with the gradations 48 are mutually offset in height so that the distance between the sleeves 46 and 47 remains substantially the same even in the beveled area. This is achieved in that the funnel-shaped area of the outer sleeve 47 is set deeper than that of the inner sleeve 46. The conditions here are therefore the reverse of those in the embodiments according to FIGS. 1 to 4. Two rows of holes 49 and 50 are used to form the individual jets provided, which are directed directly at the stepped steps 48 of the two sleeves 46 and 47. It is understandable that instead of the two sleeves with their associated rows of holes, a plurality of sleeves and rows of holes corresponding to the arrangement can also be provided. Instead of continuous radial dividing walls 15, as are provided in the annular channels of the embodiments according to FIGS. 1 to 4, only radial dividing wings 51 are provided in the present embodiment, which point outwards from the cylindrical part of the inner sleeve 46. However, they perform essentially the same function, but allow the jet aerator to be constructed from several separate funnel-shaped components.

In the water jet aerator according to the invention, the exit surface for the joint aerated water jet can also be curved downwards. Furthermore, the channels for the still separate ventilated jets can also have a diverging direction. Furthermore, simple injection molding is possible, in particular the number of components can be kept low, since several components can be formed in one piece.

Claims (18)

1. Water jet aerator for sanitary fittings and the like with at least one device (7) for generating individual jets, with at least one chamber (10) below for air access and at least one device (12) for decomposing and mixing the individual jets with air, thereby characterized in that at least two devices (12) are provided for splitting individual beams which have walls (14, 22 to 24; 34 to 36; 46 'to 48) which capture the individual beams and interact with one another, at least one wall of which extends laterally into the Obstacles (22 to 24; 34 to 36; 46 to 48) protruding from the path of the individual beams have only two opposite ones in at least one device (12) for splitting the individual beams other cooperating walls (14, 22 to 24; 34 to 36; 46 to 48) are provided and that the devices (12) for the decomposition of individual jets are so close together that the aerated jets emerge as a common aerated jet. 2. Water jet aerator according to claim 1, characterized in that the device (12) for the decomposition of individual jets in cross section is slot-shaped to annular. 3. Water jet aerator according to claim 1 or 2, characterized in that the devices (12) for decomposing the individual jets are arranged concentrically to one another. 4. Water jet aerator according to one of the preceding claims, characterized in that the walls (14, 22 to 24; 34 to 36; 46 to 48) are continued in a channel-like manner downstream of the devices (12) for decomposing the individual jets, preferably in Form of concentric cylindrical ring channels (19 to 21). 5. Water jet aerator according to claim 4, characterized in that the channels (19 to 21) have common partitions (14). 6. Water jet aerator according to one of the preceding claims, characterized in that a common device (7) for generating individual jets is assigned to several, preferably all devices (12) for decomposing the individual jets. 7. Water jet aerator according to one of the preceding claims, characterized in that the obstacles (23, 24; 34 to 36; 48) from the wall: .n protrude at least partially into the paths of the individual jets and are preferably designed in a step-like manner, the individual stages, as seen in the direction of flow of the individual jets, increasingly protrude into the passage space of the devices (12) for splitting the individual jets. 8. Ventilation device according to one of the preceding claims, characterized in that the openings of the devices (7) for generating individual jets at least partially, preferably completely, on the top step of the staircase-shaped obstacles (23, 24; 34, 35, viewed from the outlet openings) 36; 48) are prepared. 9. Jet ventilation device according to one of the preceding claims, characterized in that in the case of concentrically arranged devices (12) for decomposing the individual jets, at least the inner wall (14) has outward obstacles (23, 24; 35, 36). 10. Ventilation device according to one of the preceding claims, characterized in that both walls (14) facing each other obstacles (23, 24; 34 to 36), which are preferably offset in height from each other. 11. Water jet aerator according to one of claims 7 to 10, characterized in that from a wall (14) to a cutting device (12) on one side and to a cutting device (12) according to other side projecting obstacles are arranged at the same height and are preferably designed in cross section in the manner of a step pyramid (23, 24; 34, 35). 12. Water jet aerator according to one of claims 7 to 11, characterized in that the walls are arranged eccentrically on the obstacles (23, 24; 34 to 36), preferably represent an extension of the bottom outer step (16) downwards. 13. Water jet aerator according to claim 11 or 12, characterized in that the cross-sectional pyramid-like obstacles (23, 24; 34, 35) seen from the top common step, have a different width on both sides, in particular the number of stages and / or the step width of an obstacle is smaller, in particular in the case of obstacles (24; 34, 35) that are directed inwards from a wall. 14. Water jet aerator according to one of the preceding claims, characterized in that the narrowest point between two opposite walls in the area of the obstacles (22 to 24; 33 to 36; 48) 0.5 to 1.5 times the distance between two walls ( 14) corresponds. 15. Water jet aerator according to one of the preceding claims, characterized in that between the walls (14) vertical substantially perpendicular to the walls (14) arranged intermediate webs (15) are provided, which preferably extend to the outlet opening of the aerated jets and in particular to the outlet opening taper to the point. 16. Water jet aerator according to one of the preceding claims, characterized in that it is made entirely of plastic, in particular by injection molding. 17. Water jet aerator according to one of the preceding claims, characterized in that the devices (12) for decomposing the individual jets, optionally together with adjoining channels (19 to 21), are made in one piece from plastic and preferably receptacles for the device (7) to form the individual beams. 18. Water jet aerator according to one of the preceding claims, characterized in that it has devices, in particular threads, for direct attachment to water outlet openings of taps and the like.

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