EP3918143A1 - Method for removing a jet regulator from a fixture outlet, jet regulator, use of a jet regulator receiving area, and set consisting of a jet regulator and a tool - Google Patents

Abstract

The invention relates to a method for removing a jet regulator (1) from a fixture outlet (2), to a jet regulator (1), and to a set consisting of a jet regulator (1) and a tool (6). The jet regulator (1) has a housing (3) and a latching element (4) which is movably mounted on the housing (3). The latching element (4) can be adjusted by means of a force transmission from a spring element (5) which is arranged within a recess of the housing (3) and can be accessed from outside of the fixture outlet (2) onto the latching element (4). The latching element (4) protrudes beyond the housing (3) in the rest position in order to hold the jet regulator (1) in the fixture outlet (2), wherein a tool (6) is inserted into the fixture outlet (2) in an insertion direction (7) for removal purposes, and the spring element (5) is acted upon by the tool (6) during the insertion process until the latching element (4) releases the jet regulator (1).

Description

Process for removing a jet regulator from a valve outlet, jet regulator, use of a jet regulator holder and set of one jet regulator and one

Tool

The invention relates to a method for removing a jet regulator from a valve spout, the jet regulator having a housing and a latching element arranged movably on the housing, the latching element being accessible from outside the valve spout

Spring element is acted upon and in its rest position protrudes beyond the housing in order to hold the jet regulator in the valve outlet, a tool for removal being introduced into the valve outlet in an insertion direction.

The invention also relates to a jet regulator, the jet regulator having a housing and a latching element movably arranged on the housing, the latching element being accessible from outside the valve outlet

Spring element is acted upon and in its rest position protrudes beyond the housing in order to hold the jet regulator in the valve outlet, a tool for removal being introduced into the valve outlet in an insertion direction. By introducing the tool, for example, into a designated gap between the valve and

Jet regulator, which is formed, for example, by a gap-forming recess on the jet regulator in the position of use, the locking element can be disengaged.

Flow regulators of the type mentioned above are therefore not held in a fitting by means of a threaded connection between an outlet mouthpiece and the fitting outlet, but generally only by means of a locking mechanism on the fitting formed by the locking and spring element fixed. This means, for example, that there is no need for a spout from the fitting, which means that a more aesthetic overall impression can be achieved.

The invention further relates to a jet regulator with an outlet structure which has lamellae.

For example, the jet regulators mentioned above can be rectangular jet regulators (rectangular jet regulators).

The invention further relates to the use of a jet regulator receptacle of a fitting for completing a laterally open area of a jet regulator.

Finally, the invention relates to a set of a jet regulator and a tool.

The removal of a jet regulator from a fitting by means of a method of the aforementioned type has so far had the disadvantage that the latching element spread apart from the jet regulator housing in the inserted position of the jet regulator is difficult to remove from its rest position (in the use position, this corresponds to a fixing position) a removal position can be brought. For this purpose, a tool must be inserted into a gap between the valve and jet regulator so that it engages behind the spring element on its side facing away from the housing in order to be able to move the spring element against the insertion direction by applying force, in order to subsequently move it in the direction of the housing . Knock-in elements of a known type therefore generally lead to an axial fixation by means of support on a contact surface of the valve outlet, which extends transversely or perpendicularly to the direction of insertion. This also has the after part that a buffer space is available in the valve outlet must be in order to lift the locking element from the loading surface in the direction of insertion and then to be able to move towards the housing. However, if there is contamination in the buffer space after the jet regulator has been used for a long time, it is often extremely difficult to remove.

The invention is therefore based on the object of providing a method and a jet regulator of the type mentioned at the outset, the problems mentioned being eliminated by improving the properties of use.

The stated object is achieved according to the invention by the features according to claim 1. In particular, to solve the problem, a method of the type mentioned above is proposed in which the spring element is subjected to the tool during insertion until the locking element releases the jet regulator. A new type of unlatching mechanism is thus designed in order to be able to more easily release a jet regulator held in a fitting outlet.

Advantageous embodiments of the invention are described below, which, alone or in combination with the features of other embodiments, can optionally be combined together with the features of claim 1.

According to an advantageous embodiment it can be provided that the tool engages in an undercut oriented in the insertion direction on the jet regulator in order to be able to pull the jet regulator out of the fitting outlet. Due to the locking, a force can be transferred to the jet regulator using the tool. In order to be able to achieve a non-positive and / or positive locking, the tool can have at least one projection, preferably at least two projections, which engage in the undercut (s) on the jet regulator in the use position. Thus, a pulling mechanism can be formed. In contrast to previously known solutions, he has thus succeeded for the first time in decoupling an unlocking mechanism from a pulling mechanism. This makes it much easier to pull the jet regulator out of the valve outlet.

The at least one undercut can protrude into a gap-forming recess on the housing of the jet regulator provided for inserting the tool. In particular, the undercut can protrude transversely or perpendicularly to the direction of insertion from the housing. The at least one projection can have an inclined contact surface in the direction of the jet regulator which acts on the at least one undercut during insertion, so that the projection is deflected before it engages in the insertion direction after the undercut. The at least one projection can be arranged, for example, on a spring means of the tool.

The undercut itself can have a corresponding counter contact surface, preferably aligned parallel to the contact surface of the projection, in order to be able to force the counter contact surface onto the contact surface when the tool is inserted.

The above object is further achieved according to the invention by the features according to the independent claim 3. In particular, to solve the problem, a jet regulator of the type mentioned above is proposed, the spring element being designed and / or arranged such that a tool inserted into the fitting outlet in an insertion direction can be acted upon during insertion until the locking element releases the jet regulator.

The spring element can, for example, in a recess, for example, the previously mentioned recess on the Ge housing, which is provided for inserting the tool, be arranged.

In order to make it even easier to pull the jet regulator out of the fitting outlet, it can be provided that the spring element does not protrude beyond the housing in the rest position.

According to a further advantageous embodiment, the spring element can have at least two interconnected, in particular at an apex interconnected, legs. By acting on the spring element by means of the tool, for example by means of two rigid arms of the tool, the two legs are moved towards one another or moved away from one another until the latching element or the latching elements respectively connected to one leg no longer protrude beyond the housing. The two legs are preferably moved toward one another by the tool in a direction transverse or perpendicular to the insertion direction in order to move the latching element or the latching elements from the rest position into the release position. The tool thus presses the two legs of the spring element together, for example, in order to be able to remove the jet regulator.

The spring element is connected to the locking element or the locking elements, the locking element or locking elements being moved when the spring element is adjusted.

The locking element or the locking elements of the jet regulator protrude beyond the housing in the rest position in a direction oblique or perpendicular to the direction of insertion. Thus, the at least one locking element forms a radial locking on the armature spout. The holding force exerted by the latching element (can correspond to the tensioning force of the spring element) acts here perpendicular or almost perpendicular to the inner wall of the valve outlet.

Another independent solution is achieved by the features of the independent claim 4. In particular, according to the invention, it is proposed a jet regulator with an outlet structure which has lamellae, the lamellae being placed outwards at least in a region of the outlet structure in order to generate a divergent water flow. This enables a particularly appealing discontinued image to be created. In particular, an almost rectangular water jet can thus be generated, for example, in the case of a rectangular jet former.

According to an advantageous embodiment, it can be provided that the aforementioned region is arranged in an edge region of the outlet structure and / or that the region is arranged in a central region of the outlet structure.

With a further advantageous embodiment of the jet regulator, it can be provided that the outwardly positioned slats have a cross section oriented transversely to their extension, which has a curved outer contour. This has the advantage that a particularly good separation of individual water jets is possible, as a result of which a better jet shape can be achieved. For example, a better rectangular jet shape can be achieved in this way if it is a rectangular jet regulator.

According to a further advantageous embodiment, lamellae with a cross section oriented transversely to their extension, which has an outer contour oriented in the direction of flow, can be arranged outside the aforementioned area. These fins can therefore extend in the direction of flow. In particular, these slats are outside the The above-mentioned area is straight and leads to a stream of water flowing out in a straight line.

According to a further independent solution, which can alternatively also be seen in combination with the features mentioned above, a jet regulator is proposed, in particular as described and claimed hereinbefore, with a jet acceleration unit which has a seal circumferentially around a flow direction on the outside, and to the downstream jet form elements, in particular lamellae, are arranged which extend transversely to the flow direction, the jet form elements each having a free end with which they protrude from a carrier wall running along the flow direction. This has the advantage that the jet regulator can be manufactured using an injection molding process. In particular, the jet regulator has the advantage that a housing part and a jet former part are formed in one piece. In the case of previously known jet regulators with jet former parts for generating a divergent water flow, it was always necessary for the jet former parts to be formed separately from the housing. This makes it easier to manufacture a jet regulator with the desired properties.

A further advantageous embodiment can provide that the jet acceleration unit is formed at an upstream end of a jet ventilation area. For example, the beam acceleration unit can be designed as a perforated plate or as a diffuser-diffuser ring combination.

According to a development of the jet regulator, this can be characterized by an elongated, non-circular outer contour transverse to the direction of flow. In particular, the free ends of the jet-shaped elements can each be arranged in the position of use on a long side of the outer contour. Alternatively or in addition, the support wall can be Position on a long side of the outer contour.

According to a further advantageous embodiment, the free ends can form a laterally open area in a peripheral wall. In particular, the beam shape elements can end at a uniform height.

According to a further advantageous embodiment, the latching element can be guided in a guide formed by the housing. In particular, the guide can be designed as a slide bearing and / or it can be determined by the guide that the latching element can be adjusted in one degree of freedom, in particular only in one degree, preferably in a straight line.

In order to be able to determine more precisely how far the latching element can be extended, it can be provided according to a further advantageous embodiment that at least one stop is formed on the housing, which is acted upon by a corresponding counterstop on the latching element in a latching position. In particular, the stop can be used to define the maximum extent to which the latching element protrudes from the housing. The stop and counterstop are therefore spaced apart from one another in a release position and / or make contact in a detent position.

According to a further advantageous embodiment, the latching element and / or the spring element can be formed separately from the housing. Thus, the latching element and / or the spring element cannot be formed as part of the housing, but rather separately from it. The jet regulator can preferably have two latching elements, each of which is connected to the spring element or one spring element each. At a free end of the locking element, a locking lug can be formed, which is retracted into a release position when the spring element is actuated. By a central operation of the The spring element can thus also be adjusted the locking element or the locking elements. The latching element and / or the spring element are thus not integrally formed on the housing and can therefore be adjusted relative to the housing.

The separate configuration of the latching element and / or the spring element from the housing has the advantage that the latching lugs at the ends of the latching elements are adjustable at the same time. When the spring element or the spring elements are actuated, the latching lugs are released simultaneously. The simultaneous adjustment of the locking lugs is also possible, although they protrude from the housing on opposite sides of the jet regulator. In other words, that is, they are located far apart on opposite sides of the jet regulator. As a result, particularly good fixation of the jet regulator in the inserted state can be achieved, the release also being simplified by simply loading the central spring element. This configuration means that the spring element is not acted on at the location of the latching, but at a distance from it. This means that no space is required to insert the tool at the location of the locking.

The invention further relates to the use of a jet regulator receptacle of a fitting for completing a laterally open area of a jet regulator as described and claimed herein, the laterally open area being given by the free ends of the jet-shaped elements and the jet regulator receptacle being the laterally open area of the jet regulator used in the jet regulator holder.

The invention further relates to a set of a jet regulator, in particular as described and claimed herein, and a tool for carrying out a method such as it is described and claimed herein.

The invention will now be described in more detail using exemplary embodiments, but is not restricted to these exemplary embodiments. Further exemplary embodiments result from the combination of the features of individual or more claims with one another and / or with individual or more features of the exemplary embodiments.

It shows:

Fig. 1 shows a possible embodiment of an inventive

Jet regulator with several jet shaping elements designed as lamellae in perspective

Presentation,

2 the embodiment of FIG. 1 in a side view,

3 shows a further perspective illustration of the jet regulator mentioned above with an attached strainer,

4 shows a further perspective illustration of the aforementioned jet regulator with the attachment screen removed,

5 A longitudinal section through an embodiment of the

Jet regulator, as highlighted in FIG. 6 with the arrows identified by A,

Fig. 6 is a plan view of the aerator with inserted

Cutting lines A and B,

7 is a cross section through the imple mentation form of

Jet regulator, as highlighted in FIG. 6 with the arrows identified by B, 8 shows a set of a jet regulator and a tool, the tool not being locked onto the jet regulator (in a rear view),

9 the set from FIG. 8, the tool being locked on the jet regulator (in a rear view),

10 is an axially sectioned illustration of a jet regulator receptacle of a fitting outlet, in which a jet regulator is inserted (installation situation),

11 shows a further axially sectioned illustration of a

Flow regulator receptacle of a fitting outlet in which a flow regulator is inserted (installation situation), the locking element acting vertically on the inner wall of the flow regulator receptacle.

FIGS. 1-7 show several views of a jet regulator, designated as a whole as 1.

The jet regulator 1 is designed to be inserted into a jet regulator receptacle 25 provided for this purpose on a fitting outlet 2 in the use position and to be fixed therein.

FIGS. 1-7 each show a rectangular configuration of a jet regulator 1, which has a non-circular outer contour 23.

In order to be able to achieve the most rectangular possible beam shape, the jet regulator 1 has a special outlet structure 9. The outlet structure 9 comprises a plurality of steel shaped elements 17 arranged at a distance from one another.

The beam-shaped elements 17 comprise lamellae 10, which are arranged in at least one row on an outlet side of the jet regulator 1. The lamellae 10 form a run-out image of the total jet of a fluid flowing through. Since they are arranged in the flow path of the jet regulator 1, the entire jet flows around them.

The outlet structure 9 comprises an area 11 in which the lamellae 10 are placed outwards in order to generate a diverging water flow. For example, the slats can be bent outwards and / or arranged obliquely in comparison to the direction of flow 18. In the embodiment shown Darge said area 11 is formed in the edge areas 12. The lamellae 10 in the aforementioned area 11 have, for example, a cross section 14 with an outer contour that is bent. They therefore deflect the fluid flow.

The fins 10 in the central area 13, however, are straight and form a straight fluid flow. This means that the lamellae 10, which are arranged outside the region 11, have a cross section which has an outer contour oriented in the direction of flow. Furthermore, the two outermost slats 10 in the row of slats 10 are also straight.

The lamellae 10 each extend perpendicularly or transversely to the flow direction 18. The steel mold elements 17 are formed on a carrier wall 20 of the housing 3. The beam form elements 17 and the housing 3 are thus in one piece. The shaped steel elements 17, in particular the lamellae 10, have a free end 19, by means of which they are not arranged on a support wall 20, but are exposed. The free ends 19 of the steel mold elements 17 and the support wall 20 each form a long side of the outer contour 23 of the jet regulator 1. The steel form elements 17, in particular the lamellae 10 protrude transversely or perpendicularly from the support wall 20 into the flow path.

In the area of the free ends 19 of the jet-shaped elements 17, a peripheral wall of the housing 3 has an area 24 which is in particular open to the side. The beam shape elements 17 have a uniform length or at least a large part of the beam shape elements 17 have a uniform length. So they end at a uniform height.

A jet acceleration unit 15 is arranged upstream of the outlet structure 9 in flow protection device 18. The jet acceleration unit 15 is in turn upstream of a jet ventilation area 21 in the flow direction 18.

A liquid flowing through the jet regulator 1 thus flows first through the passage openings of the jet acceleration unit 15, then through the jet ventilation area 21, in which the liquid is mixed with air before the jet is formed in the outlet structure 9 and the jet regulator or the fittings outlet 2 leaves on the outlet side.

The jet ventilation area 21 is formed within the housing 3 in the flow path of the liquid. Arranged in the jet ventilation area 21 are a plurality of jet-shaped elements 17 which, as shown in FIGS. 1 to 7, can be designed, for example, as distributor elements 36 in order to achieve a division of the water jet and its better mixing with air sucked in from the outside through at least one air duct 37 to be able to. At least one air duct 37 is formed on the housing 3, which breaks through at least one wall of the housing 3 in order to be able to suck in air from the outside into the jet ventilation area 21 by the underpressure arising here. Preferably, the at least one air duct 37 is formed in the flow direction 18 after the seal 16. More preferably, the at least one air duct 37 can be arranged on a narrow side of the housing 3.

The air duct 37 is at least partially formed by a boundary wall 39 which extends in the flow direction 18 and which laterally delimits the flow path. The boundary wall 39 extends in the flow direction 18 over the entire area in which the jet ventilation area 21 and / or the outlet structure 9 is / are arranged. The air duct 39 can therefore run between an outer wall of the housing 3 and the boundary wall 39. An outer end of the air duct 39 can be located, for example, on the outlet side of the jet regulator 1.

The jet regulator 1 preferably has at least two air channels 37. In particular, these can be formed on opposite sides, for example narrow sides of the housing 3.

The distributor elements 36 can - similar to the previously described slats 10 - be integrally formed with the housing 3. A cross section of the distributor elements 36 can, for example, have rounded corners, in particular be round. The rounded corners make it easier to avoid noise. However, other shapes are also possible. The decisive factor here is that the distributor elements 36 represent an obstacle to flow within the flow path, which can be achieved, for example, by the distributor elements 36 having an impact surface which, in particular, extends at least partially transversely to the direction of flow 18. The distributor elements 36 of the embodiment shown are in two rows, respectively arranged side by side, the distributor elements 36 of the first and second rows being arranged offset to one another in order to be able to achieve the best possible division of a fluid flow and mixing with air.

The distributor elements 36 are formed on one or the already mentioned support wall 20 of the housing 3 and project, in particular transversely or vertically, into the flow path. Furthermore, the distributor elements 36 each have free ends 19, which form the open area 24 in the peripheral wall of the housing 3, in particular together with the lamellae 10. As shown in FIGS. 1 to 7, the distributor elements 36 have a uniform height with the lamellae 10. The fins 10 are arranged downstream of the distributor elements 36.

The laterally open area 24 extends over at least 10%, in particular at least 20%, in particular we at least 25%, in particular at least 33%, in particular at least 50%, preferably at least 60%, preferably at least 65%, preferably at least 80%, preferably at least 90%, one side of the jet regulator 1, in particular the long side of the jet regulator 1.

The jet regulator 1 has a circumferential seal 16 on the outside of the jet acceleration unit 15. By means of the seal 16, it is possible to seal an outside transition from the jet acceleration unit 15 to the downstream run structure 9 in the use position by the seal 16 resting on the inside of the fitting outlet 2.

The jet regulator receptacle 25 of the fitting outlet 2 has a stepped structure. This has the advantage that the seal 16 is not pushed over a total length of the jet regulator receptacle 25 with friction when installing and removing the jet regulator 1 must become. In the inserted state, the seal is pressed against the wall of the valve outlet 2 and pressed. It can be provided that the jet regulator receptacle 25 has a groove into which the seal 16 is inserted when inserted, the seal 16 not completely filling the groove in order to enable a better seal.

The beam acceleration unit 15 can be designed, for example, as a perforated plate 26 and / or as a diffuser-diffuser ring combination (not shown). Here, the diffuser-diffuser ring combination can have, in a manner known per se, a diffuser acting as a baffle plate, followed by an annular nozzle delimited by a rectangular diffuser ring.

In the use position of the jet regulator 1 - that is to say in the state inserted into the valve outlet 2 into a jet regulator receptacle 25 adapted for the jet regulator 1 - the jet regulator receptacle 25 covers the region 24 which is open at the side. The open area 24 is thus covered by an inner wall of the jet regulator receptacle 25. The cover does not lead to a complete seal, but a play is provided in order to allow certain tolerances. This has the advantage that the outlet structure 9 can be formed from jet-shaped elements 17 - such as, for example, from lamellae 10 and distributor elements 36 - as a part molded onto the housing 3, in particular monolithically connected to the housing 3. For example, the production can be carried out by means of an injection molding process.

FIGS. 8 to 11 show a further embodiment variant of a jet regulator 1 as a set with a tool 6, which can be embodied alone or in combination with the features of the aforementioned embodiment variant.

The jet regulator 1 has a movable on its housing 3 guided locking element 4, which can be acted upon by a spring element 5 accessible from outside the valve outlet 2 and / or wherein a force transmission from the spring element 5 to the locking element 4 is possible. In the embodiment shown, the locking element 4 is connected to the spring element. In particular, the locking element 4 and the spring element 5 can be formed in one piece, in particular monolithically.

In the rest position of the locking element 4 and / or the spring element 5, the locking element 4 projects beyond an outer side of a wall of the housing 3. In the inserted state of the jet regulator 1, the rest position corresponds to the snap-in position in which the jet regulator 1 is held in the valve outlet 2.

The spring element 5 has two legs 34 which are connected in particular at an apex. The two legs 34 spread apart in two opposite directions, in particular in the rest position, so that an angle is included between the two legs 34. About the two distal ends of the two legs 34 of the Federele element 5, a power transmission from the spring element 5 to each Weil a locking element 4 is possible because the distal ends are each connected to a locking element 4 and / or act on it. In the present case, the locking elements 4 are connected to the spring element 5 at the distal ends of the spring element 5.

A new unlocking mechanism 29 is thus created by the locking element 4 and the spring element 5. In the rest position, a force, in particular a clamping force generated by the spring element 5, acts in the radial direction and / or perpendicularly or almost perpendicularly on an inner wall of the valve outlet 2 through the latching element 4.

To remove the jet regulator 1 from the valve outlet 2 a special tool 6 is required to enable unlatching. For this purpose, the tool 6 must be inserted in an insertion direction 7 into the valve outlet 2, whereby it acts upon the spring element 5 arranged outside the housing 3 during insertion until the locking element 4 releases the jet regulator 1.

The tool 6 shown in FIGS. 8 and 9 has two rigid arms 35, one of which is designed as a handle part

Stand out body 40. The rigid arms 35 have a distance between them which is smaller than a distance between the two distal ends of the legs 34

Insertion direction 7 can fen along or parallel to a longitudinal axis and / or a central axis of the jet regulator 1.

During the insertion of the tool 6 in the Armaturenaus run 2, the two legs 34 are pressed together, so that the distance between the spread ends of the two legs 34 is reduced. The locking elements 4 protruding beyond the housing 3 in the rest position are thereby withdrawn, so that the locking is released. The at least one latching element 4 is retracted in a direction that is perpendicular or transverse to the insertion direction 7, in particular a straight line.

The at least one latching element 4 is supported by a guide 41 formed on the housing 3, which can be designed, for example, as a slide bearing 38. Furthermore, locking elements 4 and spring element 5 are held on the housing 3 by the guide 41, in particular by the slide bearing 38. The locking element 4 is adjustable by the guide 41 in a degree of freedom, preferably adjustable in a straight line.

There are two stops 42 on the housing 3 and two on the locking element 4 corresponding counter-stops 43 are formed. In a latching position, a stop 42 and a counterstop 43 act upon each other, thereby defining the maximum extent to which the latching element 4 protrudes from the housing in the latched position. In the release position, the

Stops 42 and the counter-stops 43 are not, but are each spaced apart.

Furthermore, the tool 6 has at least one projection 30, in particular two projections 30, which protrude from a spring means 33 transversely to the direction of introduction 7. At the top of the projection 30, with which this is ahead in

Insertion direction 7 is inserted, a contact surface 31 aligned obliquely to an insertion direction 7 is formed.

The tool 6 is flat, so that it can be inserted in particular on the back of the jet regulator 1. The

Spring elements 33 therefore do not have to be removed

Undercuts or detents 44 are released.

On the jet regulator 1, in particular on the housing 3 of the jet regulator 1, an undercut 8 is formed which is oriented in a guide direction 7 and which projects transversely or perpendicularly to the direction of insertion 7.

The undercut also has an oblique to the insertion direction 7 and / or at least almost parallel to the contact surface 31 of the projection 30 aligned counter contact surface 32. When the tool 6 is inserted into the armature outlet 2, the projection 30 is displaced and / or deflected against a restoring force generated by the spring means 33 at the undercut 8 until the projection 30 snaps into the undercut 8 and the tool 6 with the jet regulator 1 is locked. A pulling mechanism 28 is thus formed, which is decoupled from the unlocking mechanism 29 described above. However, decoupling the jet regulator 1 from the Arma turenauslauf 2 and coupling the jet regulator 1 with the tool 6 solely by inserting the tool 6 in particular exclusively in the insertion direction 7 in the Arma turenauslauf 2.

Coupling and unlatching thus take place almost simultaneously through the same movement. After coupling the tool 6 with the jet regulator 1, a tensile force can be applied to the jet regulator 1 in order to be able to pull the loosened jet regulator 1 against the insertion direction 7 from the valve outlet 2.

The jet regulator 1 can have a latching element 4 or a plurality of latching elements 4 which are connected to a spring element 5 or in each case to a spring element 5. However, it is advantageous if a plurality of locking elements 4 are connected to a common spring element 5 or if the locking elements 4 are each connected to a spring element 5 and the two spring elements 5 are in turn connected to one another.

The locking element 4 and / or the spring element 5 are formed separately from the housing 3 in the embodiment variant of the jet regulator 1 shown. Thus, the locking element 4 and / or the spring element 5 is / are not formed as part of the housing 3, but separately therefrom. The jet regulator 1 can preferably have two latching elements 4, each of which is connected to the spring element 5 or one spring element 5 each. At the free ends of the locking elements 4 are one

Locking nose 44 formed which when the

Spring element 5 are withdrawn simultaneously into a release position. By a central operation of the Spring element 5 can thus also the locking element 4 or

Locking elements 4 can be adjusted. The locking element 4 and / or the spring element 5 are thus not integrally formed on the housing 3 and can therefore be adjusted relative to the housing 3.

The separate configuration of the locking element 4 and / or the spring element 5 from the housing 3 has the advantage that the

Lugs 44 at the ends of the locking elements 4 are simultaneously adjustable. When the spring element 5 or the spring elements 5 are actuated, the detents 44 thus loosen at the same time. The simultaneous adjustment of the locking lugs 44 is also possible, although they protrude from the housing 3 on sides of the jet regulator 1 facing away from one another. The release takes place by simply acting on the central spring element 5. This configuration means that the spring element 5 is not acted on at the location of the

Latching, but spaced from it. This means that no space is required to insert the tool at the location of the locking.

The invention therefore relates in particular to a method for

Removing a jet regulator 1 from a fitting outlet 2, a jet regulator 1 and a set of a jet regulator 1 and a tool 6, the jet regulator 1 having a housing 3 and a latching element 4 movably mounted on the housing 3, the latching element 4 by means of a force transmission supply from an inside of a recess of the housing 3 to orderly and accessible from outside the valve outlet 2 Liche spring element 5 on the latching element 4 is adjustable, the latching element 4 protruding in its rest position over the Ge housing 3 to run the jet regulator 1 in the Armaturenaus 2 to hold, wherein a tool 6 for removal in an insertion direction 7 is inserted into the fitting outlet 2, the spring element 5 being acted upon by the tool 6 during insertion until the locking element 4 is the jet regulator 1 releases.

/ List of reference symbols

Reference drawing list

1 jet regulator

2 tap spout

3 housing

4 locking element

5 spring element

6 tools

7 Direction of insertion

8 undercut

9 Discontinued structure

10 slats

11 Area of the slats exposed to the outside

12 edge area

13 central area

14 cross section

15 beam acceleration unit

1 6 seal

17 beam formulas

1 8 flow direction

1 9 free end

20 support wall

21 jet ventilation area

22 front screen

23 outer contour

24 side open area

25 jet regulator holder

2 6 perforated plate

2 8 pulling mechanism

2 9 Unlatching mechanism

30 head start

31 contact surface

32 mating contact surface

33 spring means

34 legs 35 rigid arms

36 distributor element

37 air duct

38 plain bearings

39 boundary wall

40 basic body

41 leadership

42 stop

43 counterstop

44 latch

/ Expectations

Claims

Expectations

1. A method for removing a jet regulator (1) from a fitting outlet (2), the jet regulator (1) having a housing (3) and a movable locking element (4) on the housing (3), the locking element (4 ) is acted upon by a spring element (5) accessible from outside the valve outlet (2) and in its rest position protrudes beyond the housing (3) in order to hold the jet regulator (1) in the valve outlet (2), a tool (6) for removal in an insertion direction (7) is introduced into the valve outlet (2), characterized in that the spring element (5) is acted upon by the tool (6) during insertion until the locking element (4) releases the jet regulator (1).

2. The method according to claim 1, characterized in that the tool (6) engages in an undercut (8) oriented in the insertion direction (8) on the jet regulator (1) in order to pull the jet regulator (1) out of the fitting outlet (2) to be able to.

3. jet regulator (1), in particular for carrying out a method according to one of the preceding claims, wherein the jet regulator (1) has a housing (3) and a latching element (4) movably arranged on the housing (3), the latching element ( 4) from an outside of the

Faucet outlet (2) accessible spring element (5) is acted upon and in its rest position projects beyond the housing (3) in order to hold the jet regulator (1) in the armature outlet (2), with a tool (6) for removal in one Insertion direction (7) is introduced into the fitting outlet (2), characterized in that the spring element (5) is designed and / or arranged in such a way that it can be inserted in an insertion direction (7) into the Valve outlet (2) of inserted tool (6) can be acted upon during insertion until the locking element (4) releases the jet regulator (1).

4. jet regulator (1), in particular according to claim 3, with an outlet structure (9) having lamellae (10), characterized in that the lamellae (10) at least in an area (11) of the outlet structure (9) placed outwards to create a divergent flow of water.

5. Jet regulator (1) according to the preceding claim, characterized in that the region (11) is arranged in an edge region (12) of the outlet structure (9) and / or in that the region (11) in a central region (13) of the

Spout structure (9) is arranged.

6. jet regulator (1) according to one of claims 4 or 5, characterized in that the outwardly placed slats (10) have a cross-section oriented to their extension (14) which is a curved

Has outer contour.

7. Jet regulator (1) according to one of the preceding claims 4 to 6, characterized in that outside of the area (11), lamellae (10) are arranged with a cross-section oriented transversely to their extension, which has a flow direction (18) has aligned outer contour.

8. jet regulator (1), in particular according to one of the preceding claims 4 to 7, with a beam acceleration unit (15) which has a flow direction (18) circumferential seal (16) on the outside, and to the downstream jet-shaped elements (17 ), in particular fins (10), which extend transversely to the direction of flow (18), characterized in that that the jet-shaped elements (17) each have a free end (19) with which they protrude from a support wall (20) running along the flow direction (18).

9. jet regulator (1) according to the preceding claim, characterized in that the jet acceleration unit (15) is formed at an inflow end of a jet ventilation area (21), in particular as a perforated plate (26) and / or as a diffuser-diffuser ring combination.

10. Jet regulator (1) according to one of the preceding claims, characterized by an elongated, non-circular outer contour transverse to the flow direction (18), in particular wherein the free ends (19) of the jet-shaped elements (17) and / or the support wall (20) in each case on one Long side of the outer contour is / are arranged.

11. Jet regulator (1) according to one of the preceding claims, characterized in that the free ends (19) form a laterally open region (24) in a peripheral wall, in particular wherein the jet-shaped elements (17) end at a uniform height.

12. Jet regulator (1) according to one of the preceding claims, characterized in that the latching element (4) is guided in a guide (41) formed by the housing (3), in particular wherein the guide (41) as a slide bearing (38) is formed and / or wherein the locking element (4) through the guide (41) in one

Degree of freedom is adjustable, preferably adjustable in a straight line.

13. jet regulator (1) according to one of the preceding claims, characterized in that at least one stop (42) is formed on the housing (3) and is acted upon by a corresponding counter stop (43) on the latching element (4) in a latching position, in particular being defined by the stop (42) as the maximum the locking element (4) protrudes from the housing (3).

14. Jet regulator (1) according to one of the preceding claims, characterized in that the latching element (4) and / or the spring element (5) is / are formed separately from the housing (3).

15. Use of a jet regulator receptacle (25) of a fitting for closing off a laterally open area (24) of a jet regulator (1) according to one of claims 8 to 10, wherein the laterally open area (24) through the free ends (19) of the jet shape elements ( 17) is given and the jet regulator receptacle (25) covers the laterally open area (24) of the jet regulator (1) inserted in the jet regulator receptacle (25).

16. Set of a jet regulator (1), in particular according to one of claims 3 to 14, and a tool (6) for executing a method according to one of claims 1 or 2.

/ Summary