CZ2022305A3 - An adjustable water flow device for shower taps with automatic flow control depending on the pressure - Google Patents

Abstract

The device includes a cup (50) having an opening (52) in the middle located in a reinforced ring (54). In the opening (52) the setting regulator (40) is seated with its lower controller (43), with a pair of start-up segments (48) arranged against each other, each of them occupying the area of a circular section of up to 90º. The upper surfaces (47) of the ramp segments (48) have a starting edge (47') at the beginning of the climb and have a lift end edge (47'') at the end of the climb. The two starting edges and the ending edges are arranged on the segments (48) mirrored to each other, and the lower surfaces (42) of the segments (48) are flat. The segments (48) are supported from above by two lead-in segments (38), made on the lower face (36) of the collar (31) of the distribution element (30), which are arranged against each other and each of them occupies the surface of a circular section of up to 180º. The riser segments (38) have a starting edge (36') at the beginning of the climb and have a lift end edge (36'') at the end of the climb.

Description

Field of technology

The invention relates to a water saving device for shower faucets.

Current state of the art

Due to the ever-increasing price of water, there are devices for saving water combined with so-called aerators. The goal is to only let the water faucet release the amount of water that is needed for effective washing. This is mainly used in places where the user does not pay for water and has no motivation to save water. These are public buildings, hotels, hospitals, public sanitary facilities, etc. However, it can also be used very well in the home, especially where children or other persons who have not acquired economical habits regarding water consumption, or cannot handle the flow of water sensitively enough, wash themselves to set. Then, for example, with a lever faucet, they can comfortably release the water at full capacity, however, only the predetermined maximum flow rate will flow.

From the utility model UV 16096 U1, a water-saving device for showers is known, where a standard connecting metal piece that has two diameters. The larger upper diameter has an internal thread and the lower part with a smaller diameter is provided with an external thread, on which the shower hose is then mounted. A seat is created between the parts of the connecting piece, on which the regulator is placed from above, which is a ring with holes on the bottom and is equipped with a limiting ring that ensures its position in the smaller inner diameter of the lower part. Regulation is carried out using O-rings placed on the inner diameter of the regulator. The number of O-rings is the only possibility to adjust the flow regulation.

The aim of the invention is to present a device of the above-mentioned type, which, however, will also enable multi-stage regulation of the flow without disassembling it, just by manipulating the relevant mechanism simply from the bottom of the device.

The essence of the invention

The aforementioned shortcomings are eliminated by the adjustable water flow device for shower faucets with automatic flow control depending on the pressure according to the invention, the essence of which is that the cup has a permeable bottom with a hole in the middle, which is located in a reinforced ring, and in the hole is its lower the controller is fitted with a setting regulator, which consists of an upper stalk, and between the lower controller and the upper stalk, a setting element is made in the form of a pair of start-up segments, which are arranged opposite each other and each of them occupies an area of a circular section of up to 90°, while the upper surfaces of the run-up segments are shaped in such a way that they have a starting edge at the beginning of their ascent and a lifting trailing edge at the end of the ascent, with both starting edges and trailing edges on the segments being arranged as mirror images of each other, and the lower surfaces of the segments are flat, while the segments are abutted from above by two run-up segments, made on the lower face of the collar of the distribution element, which are arranged opposite each other and each of them occupies an area of a circular section of up to 180°, the run-up segments being shaped so that at the beginning of their rise they have a starting edge and at the end of the rise a lifting trailing edge, wherein the two starting edges and the trailing edges are mirror-imaged to each other on the segments, the upper disk being provided with under-bevel gearing, wherein two opposing elongated teeth project from the circumference of the gearing, wherein the dividing element is inserted through a hole in the support ring, and then, with its collar, it protrudes from the ring and the collar is arranged in the assembly in the lower part of the basket, while an external groove is made along the length of the outside of the also extended wall of the support ring for insertion into the two ribs on the inner circumference of the basket, and there is an internal guide groove along the length of the inside of the wall, for leading opposites

- 1 CZ 2022 - 305 A3 of extended teeth for gearing on the upper disk of the distribution element, while the internal inclined bearing surface corresponds in shape and size to the lower bevel.

In an advantageous embodiment, regularly spaced protrusions are made on the lower surfaces of the lead-in segments and there are at least two on each segment, which engage with the grooves made on the upper surface of the reinforced ring on the bottom of the cup, while the protrusions are compatible in shape with the grooves.

In another advantageous embodiment, there are ten regularly spaced protrusions and sixteen interlocking grooves.

In another advantageous embodiment, two opposite grooves are made in the area around the central opening in the dividing element, the length of which occupies a circular section longer than 90°, and the section of the groove is longer by the thickness of the stop protrusion, made on the heel of the upper stem, which is movably stored in the groove.

In another advantageous embodiment, the lower controller is provided with a control slot.

In another advantageous embodiment, the upper disc is provided with a depression in the middle.

In another advantageous embodiment, the bottom of the cup is made of flexible material capable of bending at higher water pressure.

In another advantageous embodiment, the inclined bearing surface of the support ring is provided with indentations along its circumference.

Clarification of drawings

The invention will be further presented with the help of drawings, in which Fig. 1 represents a view of a standard connecting piece into which the adjustable device according to the invention is inserted, Fig. 2 represents a view of the individual components that make up the water saving device according to the invention, Fig. 3 is a schematic cross-section of the distribution element according to the invention, Fig. 4 is a view of the distribution element from Fig. 3 from below, Fig. 5 is a schematic cross-section of the setting regulator according to the invention, Fig. 6 is a view of the setting regulator from Fig. 5 from above, Fig. 7 is a view of the setting regulator from Fig. 5 from below, Fig. 8 is a schematic cross-section of the assembly of the basket, distribution element and setting regulator, Fig. 9 is a schematic illustration of the interaction of the start-up segments of the distribution element and setting regulator, Fig. 10 is a schematic section of the device according to the invention in the assembled state before being placed in the end sleeve of the water faucet, when a minimum water flow is enabled, and Fig. 11 is a schematic cross-section of the device according to the invention in the assembled state, when a maximum water flow is enabled.

An example of a technical solution

Fig. 1 shows a view of the assembled device according to the invention stored in a fitting for connecting a shower. The armature is the aforementioned standard connecting metal piece 1, which has two outer and inner diameters. The larger upper diameter 2 has an internal thread 3 and the lower smaller diameter 4 has an external thread 5, on which the shower hose is then mounted. A seat 6 is formed between the parts of the connecting piece 1, on which the cup 50 is placed from above. All the parts of the device are then placed in it, i.e. the regulator 40, the distribution element 30 and the upper regulator 20, and the sealing ring 32 sits on top of this assembly.

Fig. 2 shows a view of the individual components that make up the water saving device according to the invention. On the left are schematic sections of individual components, and on the right are views of the respective components from above or below. The individual components will be described below the picture.

- 2 CZ 2022 - 305 A3

At the bottom, Fig. 2 shows the basket 50, into which the other components are inserted and which is the supporting element of the entire assembly. As seen on the far right in the top view, the cup 50 has a permeable bottom 51 with an opening 52 in the middle. The opening 52 is located in the reinforced ring 54, on which the grooves 55 are arranged at regular intervals and from which the spoke ribs 53 extend. In the figure on the far left, it can be seen that the wall is weakened at the top, so that between the lower rib 57 and the upper wall 57' an inclined shoulder 56 is formed. The depth of the cup 50 is, however, greater than according to the state of the art, because the length of the ribs 57 and walls 57' is also longer and the oblique shoulder 56 is arranged further from the bottom 51. The length of the ribs 57 is longer because the opening 52 the adjustment regulator 40 is installed. This is a completely new element compared to the assembly according to the state of the art and therefore a place must be prepared for it. In the figure on the right, which is a view of the inside of the cup 50, it can be seen that there are four lower ribs 57 and they are supplemented along the inner circumference of the cup 50 by two long ribs 58. They are opposite each other and there are always two lower ribs 57 at a regular distance between them The long ribs 58 serve as guides for the grooves 66 made along the length of the outside of the wall 64 at the support ring 60. This arrangement of the support ring 60 in the cup 50 is important for the reason that, again, along the length of the inside of the wall 64 is another guide groove 67 in which the toothing 34 of the dividing element 30 is guided by its opposing long teeth 38'. This possibility of a defined setting between the cup 50, the support ring 60 and the distribution element 30 is important so that during assembly one does not have to think about the mutual orientation of the distribution element 30 and the setting regulator 40. So that the lead-in segments 48 and 38 are suitably oriented against each other at any time, which affect flow regulation.

The bearing ring 60, which narrows obliquely in its lower part, abuts on the mentioned inclined support 56, thereby creating an external inclined bearing surface 61, which abuts on the inclined bearing 56. From the inside, there is an internal inclined bearing surface 62. It abuts on this with its teeth 34 or by tilting 34' the upper disc 33 of the distribution element 30. The wall 64 above the inclined bearing surfaces 61 and 62 is also longer. This is because the adjusting regulator 40 allows the dividing element 30 to be lifted by at least 2.5 mm and thus the wall 64 must be longer by this dimension. On the left is a view of the support ring 60 from above.

The distribution element 30 is pushed through the hole in the support ring 60, which then protrudes out of the ring 60 with its cylindrical collar 31, and as can be seen in the illustration on the right in the top view, the distribution element 30 on the upper disk 33 is equipped with teeth 34 with a lower bevel 34 ', while the collar 31 is then arranged in the assembly in the lower part of the basket 50. The toothing 34, unlike the state of the art, has a slant 34', as it is another element regarding the regulation of the water flow. In the basic position, the toothing 34 is supported by its bevel 34' on the internal inclined landing surface 62. When the dividing element 30 rises, the gap between the bevel 34' of the toothing 34 and the internal inclined landing surface 62 increases. This will become clear in connection with Fig. 11 and 12.

The upper regulator 20, which has a central hole 19 and is provided with a boundary ring 18 around the circumference, is still seated on the support ring 60 to secure its position in the support ring 60.

Inner collars 59 are arranged on the upper walls 57' of the cup 50, and a ring 65 is arranged on the outside of the wall 64 at the bottom. When the support ring 60 is pressed into the cup 50, the ring 65 is pushed through the collars 59 and thus the support ring 60 is secured against being pushed out of the cup 50 upwards due to water pressure.

Fig. 3 shows the distribution element 30 according to the invention. This consists of a collar 31, and an upper disk 33 is arranged on it, which is equipped with teeth 34 with a bevel 34' around the circumference and is equipped with a depression 35 in the middle. The collar 31 is equipped with a central hole 39 on the lower face 36.

In Fig. 4, which is a view of the lower face 36 of the collar 31, it can be seen that the lower face 36 is provided with two leading segments 38, which are arranged opposite each other and each of them occupies an area in the range of up to 180°, so that they cover an area of up to 360 ° from the total area of the lower forehead 36 of the collar 31 when viewed from below. The ramp segments 38 are shaped to have a starting edge 36' at the beginning of their pitch and a lift end edge 36'' at the end of the pitch. This will be explained with reference to Fig.9. The central hole 39 can also be seen. The development of the leading surfaces of the segments 38 is

- 3 CZ 2022 - 305 A3 schematically indicated on the edges of the picture. Two opposite grooves 45 are made in the area around the central opening, the length of which occupies a circular section slightly longer than 90°. The slice is longer by the thickness of the stop lug 37.

This stop protrusion 37 can be seen in Fig. 5 and also that it is arranged on the heel of the upper stem 41. It is a schematic section of the setting regulator 40 according to the invention. It consists of an upper stem 41, a lower control 43 with a control slot 44 and between them there is an adjustment element in the form of lead-in segments 48. These are arranged opposite each other and each of them occupies an area in the range of 90°, so they cover an area of 180° of the total surface 360° of the controller 40, seen from above. The upper surfaces 47 of the run-up segments 48 j are shaped so that at the beginning of their ascent they have a starting edge 47' and at the end of the ascent they have a lifting end edge 47'', while both the starting edges and the end edges are arranged mirrored to each other on the segments. This can be seen again in Fig. 9. The lower surfaces 42 of the segments 48 are flat. Protrusions 46 are indicated, which will be commented on in connection with Fig. 7.

Fig. 6 shows a view of the setting regulator 40 from above. Two ramp segments 48 are seen which are arranged opposite each other and each occupy an area of 90° so that they cover an area of 180° of the total imaginary 360° upper area of the controller 40 when viewed from above. On the heel of the upper stem 41, stop protrusions 37 are made symmetrically against each other. These can then move in the grooves 45 when the adjustment regulator 40 is turned. They serve to prevent the regulator 40 from overturning when it is rotated by 90 °. The aforementioned grooves 45 are therefore a little longer precisely by the thickness of the stop protrusion, i.e. to allow a full 90° rotation and at the same time there is room in the groove for turning the stop protrusion to the end of the groove. In the same way as a stop, the stop protrusion serves to end the revolution of the regulator when returning to the basic position. The development of the approach surfaces is again schematically indicated on the edges of the picture.

Fig. 7 shows a view of the adjustment regulator 40 from below. Two ramp segments 48 are seen which are arranged opposite each other and each occupying an area of substantially 90°, so that they cover an area of 180° of the total notional 360° lower area of the controller 40 when viewed from below. The flat bottom surface 42 of the lead-in segments 48 is provided with protrusions 46, which have a triangular cross-section. The protrusions 46 are regularly distributed along the lower surface 42 of the leading segments 48 and there are five of them on each segment 48. These fit into the grooves 55 on the reinforced ring at the bottom of the cup 50. The significance of the interaction of the projections 46 and the grooves 55 will be discussed below. When the marginal protrusion 46 with the mark min. seated in the marginal groove 55, then the flow will be the smallest and can have another four stages to achieve the greatest flow when the same protrusion 46 is seated in the end groove 55. In a schematic partial section, it is indicated how the protrusions 46 and the grooves 55 are compatible in shape. The interaction of the grooves 55 and the projections 46 ensures that the regulator 40 does not turn spontaneously and thus does not spontaneously change the flow rate due to the water pressure. The recess 35 on the upper disk 33 is used to ensure that the grooves 55 and the protrusions 46 engage with each other, because a splash of water pushes into it and the regulator 40 is pressed into the cup 50. A regulated change in flow occurs by mechanically turning the lower regulator 43 when the water stops, because at that moment the regulator 40 can be easily lifted and turned to another desired position.

Fig. 8 shows a schematic section of the assembly of the cup 50, the dividing element 30 and the setting regulator 40. It can be seen how the upper stem 41 fits into the opening 39 on the lower face of the collar 31 and the lead-in segments 38 on the lower face of the collar 31 rest on the lead-in segments 48 of the adjuster 40. And it can be seen how the adjustment regulator 40 is seated on the reinforced ring 54 of the cup 50 with its lower surface.

As indicated in the assembly of the adjustment regulator 40 stored in the basket 50 and the distribution element 30 arranged above it, the adjustment regulator 40 is rotatably seated in the basket 50 in its central opening 52, around which a central reinforced support ring 54 is arranged and this by its lower controller 43 .As indicated by the lower arrow, the adjuster 40 only rotates

- 4 CZ 2022 - 305 A3 in both directions. And as indicated by the arrow above, the distributor element 30 in turn moves up and down according to the direction of rotation of the adjustment regulator 40.

Fig. 9 explains the mutual interaction of the rise of the lead-in segments 38 on the lower face of the collar 31 of the distribution element 30 and the rise of the lead-in segments 48 on the setting regulator 40. In the figure, the risers are stretched into a plane, but in reality they are curved like the rise of a helix section. In the picture on the left, the start of the joint shot of the climb is indicated. When assembled in the basic position, the ramp segments 38 of the collar 31 and the ramp segments 48 of the setting regulator 40 are placed relative to each other so that the ramp segments 48 slide only on the upper half of the ramp segments 38. The ramp segments 47 of the setting regulator 40 and the ramp segments 38 and collars 31 are mutually arranged as follows: The start-up segments 47 of the adjustment regulator 40 occupy in the initial position half the length of the rise path of the start-up segments 38 at the collar 31. The stroke takes place on the second half of the rise path of the start-up segments, viz. image on the right - and the stroke size is marked as x. The development of the leading surfaces is schematically indicated on the edges of Fig. 4 and 6.

As soon as the lower controller 43 starts to rotate, the lead-up segments 48 at the setting regulator 40 begin to move after climbing the second half of the length of the path of the lead-up segments 38 at the collar 31 according to the arrow. With this movement, they lift the entire collar 31 over the lead-up segments 38 until the starting edges 47' come under the end edges 36'' of the lead-up segments 38 at the collar 31, which does not rotate, only moves up. After the end of the 90° climb stroke, the end edge 36'' of the lead-in segment 38 of the collar 31 comes above the starting edges 47' of the lead-in segment 48 of the setting controller 40. Due to the rotation of the lead-in segments 48, the lead-in segments 38 are raised by a distance x. During rotation, the stop protrusions 37 are raised at the same time. The height of the stop protrusions 37 must therefore be slightly higher than the distance x of the stroke, and this is so that even in the final phase of rotation of the setting regulator 40, it can rest firmly on the end of the groove 45 and thus prevent unwanted overturning the setting regulator 40.

In Fig. 10, all the components from Fig. 2 are shown in a schematic section in a compact assembly and in the cavity of the cup 50 in the state of minimum flow. The entire basket 50 is then stored in the connecting piece 1, which is screwed onto the faucet outlet. As indicated by the dotted line, the water flows through the hole 19 in the upper regulator 20. Subsequently, the water falls on the upper disk 33 into the recess 35, where it is swirled, and from there the current thus swirled flows between the teeth of the ring gear 34 and around the bevel 34' and around the inner bevel the bearing surface 62 of the support ring 60 and from there it falls on the collar 31, where the stream acquires a tubular hollow shape. The current created in this way passes through the ribbed bottom 51 of the basket 50, and flows out through the gaps between the ribs 53. There is only a small gap between the bevel 34' and the inner inclined bearing surface 62 of the support ring 60. It is clearly visible here how the stop protrusion 37 is guided in the groove 45.

In Fig. 11, all the components from Fig. 2 are in a compact assembly and in the cavity of the cup 50, but at maximum flow. The setting regulator 40 is rotated by 90° and the run-up paths on the upper surfaces of the run-up segments 48 maximally raise the pitch of the run-up segments 38 at the collar 31. Thus, the collar 31 and the entire distribution element 30 are raised by a distance x. The opening 39 is also raised by the same distance x, but above all the upper disc 33 with the teeth 34 and the bevel 34', so that a gap z is created between the bevel teeth 34' and the internal inclined bearing surface 62 of the support ring 60. This will allow a significantly greater flow of water.

If we return to Fig. 7, we can see five protrusions 46 on the lower surface 42 of the segments 48 of the adjustment regulator 40, spread regularly in five positions within the quarter circle. In Fig. 2, on the reinforced ring 54, grooves 55 arranged at regular intervals can be seen, and in these the mentioned protrusions 46 are located. There are sixteen grooves 55 and ten protrusions 46.

Fig. 10 shows the basic situation when all ten protrusions 46 are stored in their ten starting grooves 55. This is the smallest flow rate. After turning the setting regulator 40 by 90°, all ten protrusions 46 are stored in their ten end grooves 55, and in the meantime it is possible to perform four

- 5 CZ 2022 - 305 A3 turning the adjusting regulator 40, when the adjusting regulator 40 moves by one projection 46 and thereby regulates the flow. Each turn means a slight lifting of the collar 31 of the distribution element 30. With four turns, the maximum lift x of the distribution element 30 occurs, i.e. the maximum flow. In order to avoid overturning, the projections 37 reach the end of the groove 45.

With the device described, the flow can be regulated in several stages, in the presented case in five, in a very simple way, without having to remove the entire device from the faucet socket. It is of course possible to have coarser regulation, e.g. in three or even two stages with the corresponding number of grooves and protrusions. Just turn the setting regulator 40.

A final inventive feature is that the bottom 52 is made of a resilient material and when high water pressure is applied to the upper disc 33, the entire divider element 30 is pushed down against the bottom 52 causing it to bulge as indicated. At that moment, the dimension z is also throttled and the flow rate is reduced. This is an effective measure especially in the case of multi-storey buildings, eg hotels, when the water pressure decreases towards the higher floors. In the case of a consumer peak, for example in the morning when many guests are showering and flushing, without this throttling there would be insufficient pressure in the upper floors. And thanks to the throttling, the water pressure is maintained at the normal level there, even on the higher floors.

In the event that the water pressure from above would be too great and would completely push the distribution element 30 onto the inclined landing surface 62, the inclined landing surface 62 is equipped with ridges 8 around its circumference, which ensure that at least between them water will be able to flow in sufficient quantity . The notches 8 can be seen in Fig. 2 and 11.

With multi-stage regulation, it is also possible to achieve that the device reacts to a change in water pressure in the pipeline. This happens in situations where there is an immediate increase in consumption, i.e. when multiple consumption points in the building are activated at the same time or even in the event of a sudden drop in pressure in the supply pipe. At that moment, the moving part, i.e. the distribution element 30, reacts by closing or opening the slot at the lower bevel 34' depending on the water pressure and thus ensures the same amount of water at the outlet even when the water pressure fluctuates. This rise or fall of the distribution element 30 is transmitted to the intermediate piece formed by the setting regulator 40, and this rests on the ribbed bottom 51 of the basket 50 made of flexible material.

Industrial applicability

The device according to the invention can be used wherever there is a need to save water and, in particular, to gently regulate the required flow. It can also be advantageously installed, for example, in high-rise buildings where the water pressure is different on the lower floors and on the upper floors. Thanks to the flexible bottom, there is no need to set a different flow rate on each floor, because thanks to the aforementioned throttle, all devices can be set to the same flow rate. It is therefore a self-regulatory effect.

Faucets or lever faucets can be comfortably turned on fully using the device, while only the predetermined maximum flow will flow. The device prevents the formation of scale and there is a considerable saving of water and energy for the production of hot water.

Claims (8)

1. Adjustable water flow device for shower faucets with automatic flow regulation depending on the pressure containing a cup (50) and on the inner circumference bearing ribs with an oblique fit, on which a support ring (60) is arranged in the cup, on which the internal oblique bearing the upper disk of the dividing element (30) is placed on the surface and the collar (31) is pushed through the hole in the support ring (60), while the upper regulator (20) sits on top of the support ring (60), which has a hole 19 in the middle and a limiting ring around the perimeter (18), characterized by the fact that the cup (50) has a permeable bottom (51) with a hole (52) in the middle, which is located in a reinforced ring (54), while in the hole (52) it is seated with its lower controller (43) setting regulator (40), which consists of an upper stem (41), and between the lower control (43) and the upper stem (41) there is a setting element in the form of a pair of start-up segments (48), which are arranged against each other and each of them occupies the area of a circular section of up to 90°, while the upper surfaces (47) of the ramp segments (48) are shaped so that at the beginning of their climb they have a starting edge (47') and at the end of the climb they have a lifting end edge (47'') , while the two starting edges and the end edges on the segments (48) are arranged as mirror images of each other and the lower surfaces (42) of the segments (48) are flat, while the segments (48) are abutted from above by two run-up segments (38), made on the lower face (36) collars (31) of the distribution element (30) which are arranged against each other and each of them occupies a circular section area of up to 180°, the run-up segments (38) being shaped so that they have a starting edge at the beginning of their ascent (36') and at the end of the pitch they have a lifting end edge (36''), the two starting edges and the end edges being arranged mirror-image to each other on the segments, the upper disk (33) being provided with teeth (34) with the lower bevel (34 '), with two opposing elongated teeth (38') projecting from the circumference of the gearing (34), while the dividing element (30) is inserted through the hole in the support ring (60), and then protrudes from the ring (60) with its collar (31) and the collar (31) is arranged in the assembly in the lower part of the cup (50), while an external groove (66) is made along the length of the outside of the also extended wall (64) of the support ring (60) for insertion into the two ribs (58) on the inner circumference basket (50) and along the length of the inside of the wall (64) is an internal guide groove (67) for guiding the opposite elongated teeth (38') on the teeth (34) on the upper disk (33) of the dividing element (30), while the internal inclined abutment surface (62) corresponds in shape and size to the lower bevel (34'). 2. The device according to claim 1, characterized in that on the lower surfaces (42) of the lead-in segments (48) projections (46) are regularly distributed and on each segment (48) there are at least two that engage with the grooves (55) made on the upper surface of the reinforced ring (54) on the bottom of the cup (50), while the protrusions (46) are compatible in shape with the grooves (55). 3. Device according to claim 2, characterized in that there are ten regularly spaced protrusions (46) and sixteen interlocking grooves (55). 4. Device according to claim 1, characterized in that in the area around the central opening (39) two opposite grooves (45) are made in the distribution element (30), the length of which occupies a circular section longer than 90° and the section of the groove (45) it is longer by the thickness of the stop protrusion (37), made on the heel of the upper stem (41), which is movably stored in the groove (45). 5. Device according to claim 1, characterized in that the lower controller (43) is provided with a control slot (44). 6. Device according to claim 1, characterized in that the upper disk (33) is provided with a depression (35) in the middle. 7. Device according to claim 1, characterized in that the bottom (52) of the basket (50) is made of flexible material capable of bending at higher water pressure. - 7 CZ 2022 - 305 A3 8. The device according to claim 1, characterized in that the inclined bearing surface (62) of the support ring 5 (60) is provided with indentations (8) along its circumference.