阅读说明：本技术 具有带有至少一个鸭嘴阀的射流形成器的卫浴喷头 (Shower head with a jet former having at least one duckbill valve ) 是由 D·迈因卡 D·霍布罗克 于 2020-02-28 设计创作，主要内容包括：本发明涉及一种卫浴喷头(1),其至少具有：-壳体(2),-至少一个用于液体的液体输入部(3),以及-至少一个具有至少一个液体通道(19)的射流形成器(4),其中,所述至少一个液体通道(19)具有至少一个具有弹性的阀套(7)的鸭嘴阀(6),阀套在液体的流动方向(8)上从阀座(9)延伸到缝隙状的阀输出部(10),并且其中,阀套(7)至少在缝隙状的阀输出部(10)的区域中具有向外指向的加厚部(12)。(The invention relates to a shower head (1) comprising at least: -a housing (2), -at least one liquid inlet (3) for a liquid, and-at least one jet former (4) having at least one liquid channel (19), wherein the at least one liquid channel (19) has at least one duckbill valve (6) having an elastic valve sleeve (7) which extends in the flow direction (8) of the liquid from a valve seat (9) to a slit-shaped valve outlet (10), and wherein the valve sleeve (7) has an outwardly directed thickening (12) at least in the region of the slit-shaped valve outlet (10).)

1. A shower head (1) having at least:

-a housing (2),

-at least one liquid input (3) for liquid, and

-at least one jet former (4) having at least one liquid channel (19), wherein the at least one liquid channel (19) comprises at least one duckbill valve (6) with an elastic valve sleeve (7) which extends in the flow direction (8) of the liquid from a valve seat (9) to a slit-shaped valve outlet (10), the valve sleeve (7) having an outwardly directed thickening (12) at least in the region of the slit-shaped valve outlet (10).

2. Sanitary shower head (1) according to claim 1, wherein the valve sleeve (7) has a first wall thickness (13) outside the thickening (12), and in the region of the thickening (12) the valve sleeve has a second wall thickness (14) which is at least 10% greater than the first wall thickness (13).

3. Sanitary shower head (1) according to one of the preceding claims, wherein the thickening (12) is at least partially convex.

4. Sanitary shower head (1) according to one of the preceding claims, wherein the thickening (12) is at least partially concave.

5. Sanitary shower head (1) according to one of the preceding claims, wherein the thickening (12) is at least partially configured in the form of at least one bridge (15, 16).

6. Sanitary shower head (1) according to claim 5, wherein the at least one bridge (15, 16) extends from the valve seat (9) to the slit-shaped valve output (10).

7. Sanitary bathing spray head (1) according to claim 5 or 6, wherein the at least one bridge (15, 16) extends from an outer surface (17) of the valve sleeve (7) to an inner wall (18) of at least one liquid channel (19) of the nozzle (5).

8. Sanitary shower head (1) according to one of claims 5 to 7, wherein the at least one bridge (15, 16) has a bridge width (20) of 0.1 to 0.5 mm.

9. Shower head (1) according to one of claims 5 to 8, wherein the at least one bridge (15, 16) extends perpendicular to the slit-shaped valve outlet (10).

10. Sanitary shower head (1) according to one of the preceding claims, wherein the thickening (12) is at least partially elastically deformable when the slit-shaped valve output (10) is open.

Technical Field

The invention relates to a bathroom shower nozzle/shower head. Sanitary spray heads of this type can be used in showers or bathtubs, in particular for the body cleaning of people.

Background

Showers or bathtubs usually have overhead jets (which direct the flushing jet from above to the user of the shower when taking the shower) and/or hand-held jets (which the user can hold with his hands when taking the shower). Furthermore, shower heads for showers or bathtubs are known, with which liquids having different jet forms, for example in the form of rain jets, water jets, massage jets or bead jets, can be output. Switching between the individual jet forms can be effected, for example, on the shower head by means of a manually and/or electrically operated switching element (for example, depending on the type of valve or solenoid valve). By means of the switching elements, the liquid can be directed in a targeted manner to the respective jet former for forming the desired jet form. In order to control or switch the desired jet pattern, an operating element can be provided, with which a user of the shower head can adjust the desired jet pattern. When the liquid output through the shower head is stopped, it may happen that undesired liquid continues to drip out of the shower head. In order to prevent such further dripping, sanitary spray heads with outlet nozzles in the form of so-called duckbill valves are known. A duckbill valve is a valve having a valve sleeve in the shape of a duckbill. This valve is also known as a "Duckbill valve" (Duckbill-Ventile). The valve housing is at least partially made of rubber or a synthetic elastomer, such as silicone, and includes a valve seat through which liquid can flow into the duckbill valve. The valve sleeve tapers in the direction of flow of the liquid to a slit-shaped valve outlet. When the bathroom shower is not used, the slit-shaped valve output part is closed. If the inflow of liquid is activated, for example by opening a corresponding inflow valve in the inflow line of the shower head, the slit-shaped valve outlet is opened by elastic deformation of the valve sleeve due to the liquid pressure, so that the liquid can pass through the duckbill valve. After the inflow valve of the bathroom shower head is closed, the slit-shaped valve output part is automatically closed due to the reduction of the liquid pressure, thereby preventing the liquid from continuously dripping. A disadvantage of this duckbill valve is that after prolonged use of the shower head, the duckbill valve can become calcified and can then no longer be completely closed. Furthermore, particularly thin-walled duckbill valves can no longer be completely closed, particularly after a few uses. Thus, despite the duckbill valve being constructed, continued dripping of the sanitary spray head is possible.

Disclosure of Invention

It is therefore an object of the present invention to at least partially solve the problems described with reference to the prior art and in particular to provide a shower head in which the dripping of liquid is reduced or completely prevented.

This object is achieved by a shower head according to the features of the independent claims. Further advantageous embodiments of the invention are given in the dependent claims. It should be pointed out that the features which are set forth individually in the dependent claims can be combined with one another in any technically expedient manner and define further embodiments of the invention. Furthermore, the features specified in the claims are presented and explained in greater detail in the description, in which further preferred embodiments of the invention are specified.

Such a shower head contributes to this, i.e. it has at least the following components:

-a housing for the housing,

at least one liquid inlet for a liquid, and

at least one jet former having at least one liquid channel, wherein the at least one liquid channel comprises at least one duckbill valve having an elastic valve sleeve which extends in the flow direction of the liquid from a valve seat to a slit-shaped valve outlet, wherein the valve sleeve has an outwardly directed thickening at least in the region of the slit-shaped valve outlet.

The sanitary shower head can be used in particular for showers or bathtubs. Showers or bathtubs of this type can be used by the user, in particular for body cleaning purposes or therapeutic applications. For this purpose, showers or bathtubs are usually arranged in sanitary installations, for example bathrooms. Furthermore, showers or bathtubs may also be used in facilities having bathing devices, such as saunas, whirlwind bathrooms, swimming pools, and the like. The shower head is, for example, an overhead shower head or a hand-held shower head. The shower head is used for delivering liquid, in particular water. For this purpose, the shower head has a housing, which can be made at least partially of plastic and/or metal, for example stainless steel or brass. The liquid can be supplied to the shower head via at least one liquid feed. For this purpose, the shower head can be coupled to at least one rigid or flexible inflow line or inflow pipe via at least one liquid feed. For this purpose, the at least one liquid inlet is designed, for example, with a screw thread or a bayonet connection. The liquid can be output in the form of at least one jet through the shower head. In particular, the liquid can be delivered by the shower head in a plurality of jet forms, for example in two to four jet forms. The jet form may be, for example, a rain-type jet, a water column, a massage jet and/or a bead jet. In particular, when using a shower head, it is possible to deliver liquid simultaneously in only one or two different jet forms. In order to change the jet pattern, the shower head can have at least one valve in at least one liquid channel, by means of which the liquid can be guided to at least one jet former for the respective jet pattern. The at least one liquid channel extends in particular through the housing and communicates the at least one liquid inlet with the at least one jet former. Furthermore, the liquid channel can also extend, for example, through the jet former and/or the nozzles of the jet former to the outlet opening of the shower head. The shower head can have a jet former according to the jet form. The jet former has at least one nozzle and/or at least one outlet opening for the liquid, through which at least one flushing jet of a liquid, which is specific to the respective jet form, can be formed. Alternatively, the sanitary shower head can have a (single) jet former having at least one nozzle and/or at least one output opening for each jet form, wherein the at least one nozzle and/or the at least one output opening can differ for different jet forms, for example in terms of their geometry. In this case, the liquid can be (purposefully) guided to the at least one nozzle and/or the at least one outlet opening by means of the at least one valve in order to obtain the desired jet form. The at least one valve is in particular in the form of a manually or electrically operable valve, for example a solenoid valve.

At least one of the fluid passages has at least one duckbill valve with a resilient valve sleeve. In particular, at least one duckbill valve is assigned to each outlet opening of the shower head, so that each outlet opening can be closed by at least one duckbill valve. However, the outlet opening and/or the nozzle are not formed in particular by at least one duckbill valve. Instead, the at least one duckbill valve is preferably located in the sanitary shower head, in the at least one jet former and/or in the at least one nozzle of the sanitary shower head. Furthermore, at least one duckbill valve can be arranged in each nozzle of the sanitary shower head. The elastic valve sleeve is at least partially made of rubber or a synthetic elastomer, for example silicone. The valve sleeve extends in the direction of flow of the liquid from the valve seat to a slit-shaped valve outlet. The slit-shaped valve outlet extends perpendicular to the flow direction, in particular linearly, and/or in particular does not extend crosswise. The at least one duckbill valve may have a valve length in the flow direction, for example, of 1mm (millimeters) to 5mm, preferably (substantially) 2mm, from the valve seat to the valve outlet or from the valve seat to the tip of the mouth. The valve seat has in particular an inner diameter of 1mm to 3mm, preferably 1.5mm to 1.6 mm. Furthermore, the valve seat can be tubular or hose-shaped, and/or the flow cross section within the elastic valve sleeve tapers from the valve seat in the flow direction all the way to the slit-shaped valve outlet. The valve sleeve can thereby be designed in the flow direction as an inner funnel. The at least one duckbill valve is fixed to the inner wall of the at least one liquid channel, in particular by its valve seat. Furthermore, the at least one duckbill valve can be constructed in one piece, for example in the form of a casting, with the at least one liquid channel or the at least one jet former. The slit-shaped valve outlet is located on the tip of the duckbill valve and is closed when no liquid flows into the shower head. If a shower head is used, the liquid pressure which builds up in the at least one liquid channel opens the slit-shaped valve outlet by elastic deformation of the valve sleeve. If the use of the shower head is ended, so that no liquid continues to flow into the shower head and/or the at least one liquid channel, the slit-shaped valve outlet automatically closes as a result of the pressure of the liquid disappearing. The valve sleeve has an outwardly directed thickening at least in the region of the slit-shaped valve outlet. In this connection, the outward orientation means, in particular, that the thickening is formed on the outer surface of the elastic valve sleeve. The thickened portion assists the automatic closing of the slit-shaped valve outlet by (and/or at least only) increasing the restoring force of the elastic valve sleeve in the region of the slit-shaped valve outlet. This prevents the at least one duckbill valve from closing abnormally during calcification and/or due to an excessively small wall thickness and thus further dripping of liquid out of the shower head. However, the thickening preferably does not extend over the entire outer surface of the elastic valve sleeve. This prevents that at least one liquid valve cannot open or does not open sufficiently at low liquid pressures or that, in the case of a plurality of liquid valves, only a single duckbill valve is opened at low liquid pressures, so that the shower head outputs liquid with an uneven jet formation. The thickening extends in the flow direction, for example, with a thickening length of 0.2mm to 1mm, preferably 0.4mm to 0.5 mm. Furthermore, the thickened portion can be of rectilinear design. This means, in particular, that the thickened portion has a constant wall thickness at least in sections parallel to the slit-shaped valve outlet. In this case, the tip can furthermore be (substantially) rectangular and/or have a mouth thickness of 0.5mm to 2mm, preferably (approximately) 0.8 mm. With this type of thickening, the closing of the slit-shaped valve outlet is assisted without changing the opening behavior of the slit-shaped valve outlet.

Outside the thickened portion, the valve sleeve can have a first wall thickness and in the region of the thickened portion a second wall thickness which is at least 10% greater than the first wall thickness. The first wall thickness and/or the second wall thickness can be measured, in particular, perpendicularly to the inner surface of the valve sleeve. Furthermore, the first wall thickness may be 0.1mm to 0.5mm, preferably (about) 0.2 mm.

The thickened portion can be at least partially convex. In particular, the thickened portion is at least partially convex, viewed opposite to the flow direction. This can mean that the second wall thickness is greatest in the center of the slit-shaped valve outlet and decreases outwards parallel to the slit-shaped valve outlet. By means of a thickening of this type, the closing of the slit-shaped valve outlet is assisted, wherein a higher liquid pressure is required for opening the center of the slit-shaped valve outlet than outside the center of the slit-shaped valve outlet.

The thickened portion can be at least partially concave. In particular, the thickened portion is at least partially concave, viewed opposite to the flow direction. This can mean that the second wall thickness is smallest in the center of the slit-shaped valve outlet and increases outwards parallel to the slit-shaped valve outlet. The closing of the slit-shaped valve outlet is assisted by a thickening of this type, wherein the central region of the slit-shaped valve outlet opens more quickly when the slit-shaped valve outlet is opened, since less material has to be pressed or elastically deformed in the central region of the slit-shaped valve outlet.

The thickening can be at least partially configured in the form of at least one bridge. The at least one bridge is in particular formed in a wall shape. The at least one bridge is in particular elastically deformable when the slit-shaped valve outlet is open. In particular, the at least one bridge can thereby assist the closing of the slit-shaped valve outlet by means of a restoring force. The at least one duckbill valve has, in particular, a first bridge portion and a second bridge portion. The first and second webs are located on opposite sides of the valve sleeve in particular with respect to the slit-shaped valve outlet. Furthermore, the first and second webs are in particular flush with one another.

At least one bridge part can extend from the valve seat to the slit-shaped valve outlet. In particular, the at least one bridge portion extends from the valve seat to the tip of the at least one duckbill valve.

The at least one bridge may extend from an outer surface of the valve housing to an inner wall of the at least one fluid channel.

The at least one bridge may have a bridge width of 0.1 to 0.5mm, preferably the at least one bridge has a bridge width of (substantially) 0.2 mm.

At least one bridge can extend perpendicular to the slit-shaped valve outlet.

The thickened portion can be at least partially elastically deformed when the slit-shaped valve outlet is opened. By elastic deformation of the thickened portion, energy can be stored in the thickened portion for closing the slit-shaped valve outlet.

Drawings

The present invention and the technical field are explained in detail below with reference to the accompanying drawings. It should be noted that the figures show particularly preferred embodiment variants of the invention, without however being limited thereto. Here, like components are provided with like reference numerals in the figures. Wherein exemplarily and schematically:

fig. 1 shows a shower head;

fig. 2 shows a first embodiment variant of a duckbill valve of a shower head in a first sectional view;

figure 3 shows a first embodiment variant of a duckbill valve in an enlarged detail view;

figure 4 shows a first embodiment variant of a duckbill valve in a second sectional view;

fig. 5 shows a second embodiment variant of a duckbill valve of a shower head in a sectional view;

fig. 6 shows a third embodiment variant of a duckbill valve of a shower head in a sectional view;

fig. 7 shows a fourth embodiment variant of a duckbill valve of a shower head in a perspective sectional view; and is

Fig. 8 shows a fourth embodiment variant of a duckbill valve of a shower head in a further sectional view.

Detailed Description

Fig. 1 shows a shower head 1 in a side perspective view. The shower head 1 is designed here in the form of a hand shower head and has a housing 2 provided with a liquid feed 3. The shower head 1 can be connected to a supply hose, not shown here, by means of a liquid supply 3. Via the supply hose, the sanitary fitting 1 can be supplied with liquid, which enters the housing 2 of the sanitary shower head 1 via the liquid supply 3. Within the housing 2, the liquid can be supplied to the jet former 4 of the shower head 1 via channels and/or valves, not shown here. The jet former 4 has a plurality of nozzles 5, through which nozzles 5 liquid in the form of a desired jet, for example as a rain-like jet, is output to the environment 21 when the shower head 1 is in use.

Fig. 2 shows a first embodiment variant of a duckbill valve of the nozzle 5 of the jet former 4 in a sectional view along the sectional line II-II shown in fig. 1. The nozzle 5 extends vertically downwards from a circular jet former pad 22. Furthermore, the nozzle 5 has a liquid channel 19 which extends through the jet former pad 22 to an output opening 23. When using the shower head 1, the liquid which enters the housing 2 of the shower head 1 through the liquid inlet 3 shown in fig. 1 flows through the liquid channel 19 in the flow direction 8 and from the nozzle 5 through the outlet opening 23 into the environment 21. Arranged in the liquid channel 19 is a duckbill valve 6, which is located upstream of the outlet opening 23 in the flow direction 8. The duckbill valve 6 has an elastic valve sleeve 7 which extends in the flow direction 8 from a valve seat 9 to a slit-shaped valve outlet 10. The valve sleeve 7 is fixed on the valve seat 9 on the inner wall 18 of the liquid channel 19 and has a valve seat diameter 26, which is here (approximately) 1.6 mm. The valve seat diameter 26 corresponds in the region of the valve seat 9 to the passage diameter 27 of the liquid passage 19. The valve sleeve 7 therefore has a circular inner diameter 24 in the region of the valve seat 9. Starting from the valve seat 9, the valve sleeve 7, in particular the inner diameter 24 of the valve sleeve 7, tapers in the flow direction 8 in a funnel-like manner at a taper angle 32 of (approximately) 45 ° in this case to the slit-like valve outlet 10 at the tip 25 of the duckbill valve 6. Therefore, the inner diameter 24 of the valve sleeve 7 changes from a circular shape to an elliptical, (substantially) rectangular or linear shape from the valve seat 9 to the slit-shaped valve outlet 10. The duckbill valve 6 has a valve length 11 of (approximately) 2mm from the valve seat 9 to the tip 25. When sanitary fitting 1 is in use, the liquid flowing into duckbill valve 6 through liquid channel 19 in flow direction 8 elastically deforms valve sleeve 7 as a result of the liquid pressure, so that slit-shaped valve outlet 10 opens and thus opens. After use of the sanitary fitting 1, the slit-shaped valve outlet 10 is automatically closed, so that dripping of liquid from the outlet opening 23 can be prevented.

Figure 3 shows the tip 25 of a first embodiment variant of the duckbill valve 6 in the region III shown in figure 2. In the region of the slit-shaped valve outlet 10, that is to say in the region of the tip 25, the valve sleeve 7 has an outwardly directed thickening 12. Outside the thickened portion 12, the valve sleeve 7 has a first wall thickness 13 and in the region of the thickened portion 12 a second wall thickness 14 which is greater than the first wall thickness 13. The first wall thickness 13 (about) is 0.2 mm. The first wall thickness 13 and the second wall thickness 14 are measured perpendicular to the inner surface 29 of the valve housing 7. Starting from the outer surface 17 of the valve sleeve 7, the thickening 12 rises with a projection height 28. Furthermore, the thickening 12 has a thickening length 30 in the flow direction 8, which is (approximately) 0.45mm here. Furthermore, the thickening 12 (perpendicular to the flow direction 8 and/or perpendicular to the slit-shaped valve outlet 10) leads to a mouth thickness 31 of the mouth tip 25 of the duckbill valve 6, which mouth thickness is here (approximately) 0.8 mm.

Fig. 4 shows the nozzle 5 of the jet former 4 along the section line IV-IV shown in fig. 2. Fig. 4 is a plan view of the valve sleeve 7 of the duckbill valve 6, in particular, in the region of the liquid channel 19. In this case, in particular, the tip 25 of the duckbill valve 6 with the thickened portion 12 and the slit-shaped valve outlet 10 can be seen. The slit-shaped valve outlet 10 has an outlet width 33 of (approximately) 1.3mm here. In a first embodiment variant of the duckbill valve 6, the thickening 12 is straight. This means that a thickening 12 parallel to the slit-shaped valve outlet 10 results in a constant nozzle thickness 31.

Figure 5 shows a second embodiment variant of the duckbill valve 6 from the same perspective as the first embodiment variant of the duckbill valve 6 shown in figure 4. In contrast to the first embodiment variant, the thickened section 12 is of convex design. This means in particular that the thickening 12 does not run straight parallel to the slit-shaped valve outlet 10, but rather (at least) in the region of the tip 25 runs convexly. The second wall thickness 14 is therefore greatest in the center of the slit-shaped valve outlet 10 and decreases parallel to the slit-shaped valve outlet 10 toward the outside. In other respects, the second variant embodiment of the duckbill valve 6 is constructed identically to the first variant embodiment.

Figure 6 shows a third embodiment variant of the duckbill valve 6 from the same perspective as the first embodiment variant of the duckbill valve 6 shown in figure 4. In contrast to the first embodiment variant, the thickened portion 12 is concave. This means in particular that the thickening 12 does not run straight parallel to the slit-shaped valve outlet 10, but rather (at least) in the region of the tip 25 runs concavely. The second wall thickness 14 is therefore smallest in the center of the slit-shaped valve outlet 10 and increases outwards parallel to the slit-shaped valve outlet 10. In other respects, the third embodiment variant of the duckbill valve 6 is constructed identically to the first embodiment variant.

Figure 7 shows a fourth embodiment variant of a duckbill valve 6 in a perspective sectional view through the nozzle 5 of the jet former 4 along the sectional line IV-IV shown in figure 2. The fourth embodiment variant of the duckbill valve 6 differs from the first embodiment variant in that the thickening 12 comprises a first bridge 15 and a second bridge 16, which extend on both sides of the valve outlet 10 and are perpendicular to the slit-shaped valve outlet 10.

Figure 8 shows a fourth embodiment variant of the duckbill valve 6 from the same perspective as the first embodiment variant of the duckbill valve 6 shown in figure 4. The first bridge 15 and the second bridge 16 extend perpendicular to the drawing plane from the tip 25 to the valve seat 9 and parallel to the drawing plane from the outer surface 17 of the valve sleeve 7 to the inner wall 18 of the liquid channel 19. Furthermore, the first bridge 15 and the second bridge 16 have a bridge width 20, here (approximately) 0.2 mm.

By the invention, the liquid can be reduced or completely prevented from continuously dripping from the bathroom spray head.

List of reference numerals

1 shower nozzle

2 casing

3 liquid input part

4-jet former

5 spray nozzle

6 duckbill valve

7 valve pocket

8 direction of flow

9 valve seat

10 valve output

11 valve length

12 thickened part

13 first wall thickness

14 second wall thickness

15 first bridge part

16 second bridge part

17 outer surface

18 inner wall

19 liquid channel

20 bridge width

21 environment

22-jet former pad

23 outlet opening

24 inner diameter

25 tip of mouth

26 valve seat diameter

27 diameter of channel

28 height of projection

29 inner surface

30 thickened part length

31 mouth thickness

Angle of taper of 32 degrees

33 output section width.