EP3670767B1 - Sanitary insert unit - Google Patents

Description

The invention relates to a sanitary insert unit, which can be mounted in the water outlet of a sanitary outlet fitting, with a flow rate regulator unit which has at least one annular throttle body made of elastic material in at least one annular flow channel, which has at least one throttle body between itself and an adjacent one which carries a control profile Channel wall delimits a control gap, the passage cross-section of which can be changed by the throttle body, which deforms under the pressure difference that forms during flow, and with a jet regulator arranged on the outflow side of the flow rate regulator unit, which has a jet splitter, which divides the water coming from the flow rate regulator unit into a A large number of individual beams are divided.

From the DE 10 2015 003 246 A1 A sanitary insert unit of the type mentioned at the beginning is already known, which includes an inflow-side flow rate regulator unit and a downstream-side jet regulator. While the flow rate regulator unit has to regulate the amount of water flowing through per unit of time to a set maximum value, the water in the jet regulator is formed into a homogeneous, non-splashing and pearly-soft water jet. The flow rate regulator unit has two annular flow channels arranged concentrically to one another, in each of which an annular throttle body made of elastic material is inserted. The throttle bodies each delimit a control gap between themselves and a control profile which is provided on an adjacent channel wall of the associated flow channel, the passage cross section of which can be changed by the throttle body which deforms under the pressure difference that forms during flow. The downstream side arranged jet regulator has a jet splitter which is designed as a diffuser and has a baffle surface which deflects the incoming water radially outwards towards an annular wall. In this ring wall there are flow holes distributed over the circumference of the wall, through which the deflected water is divided into individual jets. These flow holes open into an annular gap that narrows in the flow direction and creates a negative pressure on the outflow side. This negative pressure allows ambient air to be sucked into the insertion housing of the previously known insertion unit, where it is mixed with the water flowing through on the outflow side of the diffuser serving as a jet splitter.

However, jet regulators with a jet splitter designed as a diffuser can be used advantageously, especially in a certain area of application, especially at low water pressures.

From the DE 10 2013 004 076 A1 We already know a sanitary insertion unit consisting of an inflow flow regulator and a downstream jet regulator. The jet splitter of the jet regulator used in the previously known insertion unit has a central hole-free baffle surface, which is delimited on the inflow-side end face of the jet splitter by an outer first annular wall, which has passage openings oriented in the radial direction and passing through it, on the side arranged in the baffle plane The through-openings each have a flow hole connected to the through-openings through the jet splitter. The outer first annular wall is surrounded on the outer circumference by an annular annular space. Coaxial and concentric with this outer first ring wall is one of these Spaced-apart, internal second ring wall of smaller diameter is provided, which has radial passage openings arranged at a distance above the baffle surface, through which the water has access to the first ring wall and to its passage openings and thus to the flow holes of the jet splitter. Since the water coming from the flow rate regulator is in the DE 10 2013 004 076 A1 known insertion unit is first deflected radially outwards on the central hole-free baffle surface in order to flow there through the passage openings provided in the inner ring wall into the associated flow hole of the jet splitter, the water flowing from the flow rate regulator unit of the previously known insertion unit cannot flow directly and flow unchecked through the flow holes in the jet splitter and the jet splitter flows out DE 10 2013 004 076 A1 The previously known sanitary insertion unit acts more like a conventional diffuser, in which the incoming water on the inflow side of the jet splitter is also initially deflected outwards at right angles to the flow direction of the jet regulator. The flow rate regulator connected upstream on the inflow side DE 10 2013 004 076 A1 The previously known sanitary insert unit has only one annular flow channel, the projection of which is aligned in the flow direction with the hole-free baffle surface. This combination should make the amount of water flowing through the aerator practically independent of the water pressure prevailing in front of the aerator.

There is therefore the task of creating a sanitary insertion unit of the type mentioned at the beginning, which is characterized by a wider range of uses or can be used advantageously in other areas of application, whereby the speed of the water flowing from the flow rate regulator unit should be controlled in such a way that it does not come out as a hard jet of water.

The solution to this problem according to the invention in the sanitary insertion unit of the type mentioned at the outset is, in particular, that the jet splitter is designed as a perforated plate, that the projection of at least one of the flow channels is arranged in a hole-free ring zone of the jet splitter, and that the flow channels are arranged outside the projection of the flow channels Flow holes of the jet splitter designed as a perforated plate are arranged on at least one circular path in the perforated plate in such a way that the water flowing from the flow rate regulator unit flows directly and unbraked through these flow holes in the jet splitter.

The insertion unit according to the invention can be mounted on the water outlet of a sanitary outlet fitting. The insertion unit has an inflow-side flow rate regulator unit, on the outflow side of which a jet regulator is provided. While the flow rate regulator unit has to regulate the amount of water flowing through per unit of time to a fixed maximum value regardless of pressure, the jet regulator of the insertion unit according to the invention is intended to form the water emerging there into a homogeneous, non-splashing and possibly also pearly-soft water jet.

The flow rate regulator unit of the insertion unit according to the invention has at least one annular flow channel in which an annular throttle body made of elastic material is provided. The throttle body located in the at least one flow channel delimits a control gap between itself and an adjacent channel wall having a control profile, the passage cross section of which can be changed by the throttle body which deforms under the pressure difference that forms during flow. The one located on the downstream side of the flow rate regulator unit The aerator has a jet splitter, which divides the water coming from the flow rate regulator unit into a large number of individual jets. This beam splitter is designed as a perforated plate in the insertion unit according to the invention. So that the water flowing from the flow rate regulator unit, possibly at high speed, cannot flow directly through the flow holes of the jet splitter and then emerge as a hard water jet at excessive speed, it is provided according to the invention that the projection of at least one of the flow channels in a hole-free ring zone of the jet splitter is arranged. A hole-free ring zone is therefore provided in the jet splitter in the axial extension of at least one of the flow channels. In contrast, the flow holes arranged outside the projection of the flow channels in the jet splitter designed as a perforated plate are arranged on at least one circular path in the perforated plate in such a way that the water flowing from the flow rate regulator unit can flow directly and unbraked through the flow holes in the jet splitter. The insertion unit according to the invention is characterized by an advantageous mode of operation even over large and in particular higher pressure ranges.

In addition to the features described above, an advantageous embodiment according to the invention provides that at least one flow hole is provided in the central region of the jet splitter delimited by the projection of the at least one flow channel.

Since in this embodiment according to the invention at least one flow hole is also provided in the central area of the jet splitter, the formation of an outlet jet that is homogeneous in the jet cross section and non-splashing in the jet regulator of the insertion unit according to the invention favored.

A particularly advantageous embodiment according to the invention, which is characterized by minimized performance deviations, provides that the flow rate regulator unit has at least two flow rate regulators, the flow channels of which are preferably arranged approximately concentrically to one another.

In order to be able to keep the hole-free ring zone in the jet splitter provided in the extension of at least one of the flow channels as narrow as possible, and in order to be able to place as many flow holes as possible in the partial area of the jet splitter lying outside the flow channels, it is advantageous if the flow channels of two adjacent flow rate regulators have an annular wall are separated from each other, and if the control profiling of these flow channels is provided on the inside and outside of this ring wall.

The formation of a homogeneous outlet jet in the jet regulator of the insertion unit according to the invention is favored if the flow holes of the jet splitter arranged outside the projection of the at least one flow channel are at least a circular path and preferably on at least two circular paths.

A preferred embodiment according to the invention provides that the circular paths having the flow holes are arranged concentrically to one another and/or to the projection of the at least one flow channel.

In the insertion unit according to the invention, a jet splitter designed as a perforated plate is preferred, the flow holes of which have a round clear hole cross section. A preferred embodiment according to the invention, which is characterized by particularly good functionality, provides that the flow holes of the jet splitter have an inflow hole section and an outflow hole section. While the inflow hole section can taper in a funnel shape in the flow direction, it is advantageous if the outflow section has a cylindrical clear hole cross section.

The functional operation of the insertion unit according to the invention and its flow rate regulator unit is favored if a throttle body with a smaller cross section, in particular a smaller cord thickness, is provided in the flow channel having a smaller diameter, compared to that in the one on the outside, which has a larger diameter Throttle body located in the flow channel.

Further developments according to the invention result from the following description of a preferred exemplary embodiment in conjunction with the claims and the drawing. The invention is described in more detail below using a preferred exemplary embodiment.

Fig. 1

eine sanitäre Einsetzeinheit in einer teilweise längsgeschnittenen Perspektivdarstellung, wobei die Einsetzeinheit eine Durchflussmengenregler-Einheit und einen auf der Abströmseite dieser Durchflussmengenregler-Einheit angeordneten Strahlregler hat,

Fig. 2

die Einsetzeinheit aus Figur 1 in einem Längsschnitt, und

Fig. 3

die Einsetzeinheit aus Figur 1 und 2 in einer Draufsicht auf die Zuströmseite eines im Strahlregler befindlichen Strahlzerlegers sowie des zuströmseitig vorgeschalteten Durchflussmengenreglers.

It shows:

Fig. 1

a sanitary insertion unit in a partially longitudinally sectioned perspective view, the insertion unit having a flow rate regulator unit and a jet regulator arranged on the outflow side of this flow rate regulator unit,

Fig. 2

the insertion unit Figure 1 in a longitudinal section, and

Fig. 3

the insertion unit Figures 1 and 2 in a plan view of the inflow side of a jet splitter located in the jet regulator and of the flow rate regulator connected upstream on the inflow side.

In the Figures 1 to 3 a sanitary insert unit 1 is shown, which can be mounted on the water outlet of a sanitary outlet fitting. The insertion unit 1 has an insertion housing 2, which carries a radially projecting annular flange 3 on the circumference in its inflow-side edge region. The insert housing 2 can be inserted into a sleeve-shaped outlet mouthpiece until the annular flange 3 rests on an annular shoulder on the inner circumference of the outlet mouthpiece, not shown here.

The insertion unit 1 has a flow rate regulator unit 4, which regulates the amount of water flowing through per unit of time to a fixed maximum value, regardless of pressure. In at least one, essentially annular flow channel 5, 6 of the flow rate regulator unit 4, an annular throttle body 7, 8 made of elastic material is provided, which between itself and an adjacent channel wall, which has a control profile 24 made up of indentations and recesses 11 oriented in the flow direction. 12 carries a control gap 13, the passage cross section of which is limited by the changes under the pressure difference forming during flow through the deforming throttle bodies 7, 8. Depending on the water pressure, the throttle body in the flow channels 5, 6, each forming a flow rate regulator, shapes itself more or less into the control profile 24 and the clear control gap 13 changes accordingly.

The flow rate regulator unit 4 here has two concentric flow channels 5, 6, in each of which an elastic throttle body 7, 8 is inserted. In this case, a throttle body 7 is provided in the inner flow channel 5, which has a smaller diameter, which has a smaller material cross-section, in particular a smaller cord thickness, compared to the throttle body 8 located in the outer flow channel 6, which has a larger diameter, and is therefore lighter reacts to low water pressures and changes in water pressure.

On the outflow side of the flow rate regulator unit 4, a jet regulator 9 is arranged, which is intended to form the incoming water into a homogeneous, non-splashing and possibly pearly-soft water jet. This jet regulator 9 has a jet splitter 10 designed as a perforated plate with a plurality of flow holes 29, which jet splitter 10 initially divides the water coming from the flow rate regulator unit 4 in the insert housing 2 into a large number of individual jets.

So that the water flowing from the flow rate regulator unit 4 at a high speed does not flow directly and unchecked through the flow holes 29 in the jet splitter 10, the projection of at least one of the flow channels 5, 6 is arranged in a hole-free ring zone 27 of the jet splitter 10, that is in the axial extension of at least one of the flow channels 5, 6 is hole-free Ring zone 27 of the beam splitter 10 is provided.

In the flow holes 29 of the perforated plate, the water flowing through exits at an increased speed, which causes a negative pressure on the outflow side of the perforated plate, which negative pressure sucks ambient air into the interior of the insert housing 2. For this purpose, ventilation openings 28 are provided in the housing wall of the insert housing 2 in the ring zone located directly below the jet splitter 10, which is designed as a perforated plate. The individual jets coming from the jet splitter 10 are mixed with the ambient air inside the housing of the insert housing 2 - in the mixing zone located inside the housing below the jet splitter 10. In order to further promote this mixing and to slow down the water further, 2 insert parts 14, 15 can be inserted in the insert housing 2, which have a grid or network structure made up of webs 17, 18 crossing each other at intersections within an external annular wall 16.

Here, concentric webs 17 intersect with radial webs 18 and form a network structure on which the water is further divided and mixed. A flow straightener 19 with outlet openings 20 adjoins the insert parts 14, 15 on the downstream side, which outlet openings 20 have a comparatively high longitudinal extent compared to the hole cross section. In the outlet openings 20 of this flow straightener 19, the water emerging there is formed into a homogeneous outlet jet. The flow straightener 19 forms the outlet-side end face of the insertion unit 1. A housing constriction 21 is provided on the outflow side of the flow straightener 19, which prevents unwanted splashing to the side of the emerging water jet.

So that the water does not emerge as an unstable ring jet and so that the emerging water also has a homogeneous jet cross section, there is at least one flow hole 29 and - as here - preferably several flow holes 29 in the central region 22 of the jet splitter delimited by the projection of the at least one flow channel 5, 6 intended.

So that a sufficient number of flow holes 29 can still be placed in the perforated plate serving as a jet splitter 10 despite the hole-free ring zone 12, the flow channels 5, 6 are separated from one another by an annular wall 23, with the control profiles 24 of the flow channels 5, 6 arranged concentrically to one another the inside and the outside of this ring wall 23 are provided. In this way, the hole-free ring zone 27 can be made comparatively narrow.

The flow holes 29 of the jet splitter 10, which are arranged outside the projection of the flow channels 5, 6, are arranged on at least one circular path and - as here - preferably on at least two circular paths. The circular paths having the flow holes 29 are arranged concentrically to one another and to the projection of the at least one flow channel 5, 6.

As can be seen in particular from the longitudinal section in Figure 2 As becomes clear, the flow holes 29 in the jet splitter 10 designed as a perforated plate have an inflow hole section 25 and an outflow hole section 26. While the inflow hole section 25 tapers in a funnel shape in the flow direction, the outflow hole section 26 has a substantially cylindrical clear hole cross section.

Reference symbol list

1

Insertion unit

2

Insert housing

3

Ring flange

4

Flow rate regulator unit

5

internal flow channel

6

external flow channel

7

internal throttle body

8th

external throttle body

9

Aerator

10

Beam splitter

11

indentations

12

Formations

13

Tax gap

14

Insert part

15

Insert part

16

Ring wall

17

concentric webs

18

radial webs

19

Flow straightener

20

Outlet openings of the flow straightener 19

21

Housing constriction

22

Central area

23

ring wall

24

Rule profiling

25

Inflow hole section

26

Outflow hole section

27

ring zone

28

Ventilation openings

29

Flow holes

Claims (10)

1. Sanitary insert unit (1) which can be fitted on the water outlet of a sanitary outlet fitting, with a throughflow-quantity regulator unit (4) which, in at least one annular throughflow channel (5, 6), has at least one annular flow-restricting body (7, 8) of elastic material, which at least one flow-restricting body (7, 8), between itself and an adjacent channel wall bearing a control profiling (24), bounds a control gap (13), the passage cross section of which can be varied by the flow-restricting body (7, 8) deforming under the differential pressure forming during the flow therethrough, and with a jet regulator (9) which is arranged on the outflow side of the throughflow-quantity regulator unit (4) and has a jet splitter (10), which jet splitter (10) divides the water coming from the throughflow-quantity regulator unit (4) into a multiplicity of individual jets, characterized in that the jet splitter (10) is designed as a perforated plate, in that the projection of at least one of the throughflow channels (5, 6) is arranged in a perforation-free annular zone (27) of the jet splitter (10) designed as a perforated plate, and in that the throughflow holes (29) of the jet splitter (10) designed as a perforated plate, which throughflow holes (29) are arranged outside the projection of the throughflow channels (5, 6), are arranged on at least one circular path in the perforated plate in such a manner that the water arriving from the throughflow-quantity regulator unit can flow directly and unbraked through said throughflow holes (29) in the jet splitter (10).
2. Sanitary insert unit according to Claim 1, characterized in that at least one throughflow hole (29) is provided in the central region (22) of the jet splitter (10), which central region is bounded by the projection of the at least one throughflow channel (5, 6).
3. Sanitary insert unit according to Claim 1 or 2, characterized in that the throughflow-quantity regulator unit (4) has at least two throughflow-quantity regulators, the throughflow channels (5, 6) of which are arranged approximately concentrically with respect to each other.
4. Sanitary insert unit according to Claim 3, characterized in that the throughflow channels (5, 6) of two adjacent throughflow-quantity regulators are separated from each other by an annular wall (23), and in that the control profilings (24) of said throughflow channels (5, 6) are provided on the inner side and the outer side of said annular wall (23).
5. Sanitary insert unit according to one of Claims 1 to 4, characterized in that the throughflow holes (29) of the jet splitter (10), which throughflow holes are arranged outside the projection of the at least one throughflow channel (5, 6), are preferably arranged on at least two circular paths.
6. Sanitary insert unit according to one of Claims 1 to 5, characterized in that the circular paths having the throughflow holes (29) are arranged concentrically with respect to one another and/or with respect to the projection of the at least one throughflow channel (5, 6) .
7. Sanitary insert unit according to one of Claims 1 to 6, characterized in that the throughflow holes (29) of the jet splitter (10) have an inflow hole portion (25) and an outflow hole portion (26).
8. Sanitary insert unit according to Claim 7, characterized in that the inflow hole portion (25) of the throughflow holes (29) tapers in a funnel-shaped manner in the throughflow direction.
9. Sanitary insert unit according to Claim 7 or 8, characterized in that the outflow hole portion (26) has a cylindrical clear hole portion.
10. Sanitary insert unit according to one of Claims 1 to 9, characterized in that the throughflow channel (5) having a smaller diameter is provided with a flow-restricting body (7) with a smaller cross section, in particular with a smaller chord size, in comparison to the flow-restricting body (8) located in the throughflow channel (6) which is external to the throughflow channel (5) and has a larger diameter.

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