EP2914784A1 - Jet regulator - Google Patents

Abstract

Disclosed is a jet regulator (100) comprising a jet regulator housing (2), in the housing interior of which a hole panel (5) is provided with a plurality of flow-through holes (6) for dividing the streaming water. The jet regulator described is characterised in that at least one flow-through hole (6) extends conically towards its outflow side in at least one outflow-side hole section. It is also possible for flow obstacles to be provided on the outflow side of the hole plate (5) in the jet regulator housing (2) and/or on the outflow front face of the jet regulator housing, which are arranged or concentrated there in a central or middle region and which deflect the streaming water into an outer annular zone. This jet regulator (100) enables an aerated and thereby sparkling-soft water jet to be generated even with low flow-through performances and low water pressures (cf. figure 12).

Description

 Strahlregier

The invention relates to a jet regulator with a jet regulator housing, in the housing interior of which a perforated plate having a plurality of flow holes for dividing the water flowing through is provided.

Jet regulator of the type mentioned are already known in various designs. Such jet regulators are mounted on the water outlet of a sanitary outlet fitting in order to produce a homogeneous and laterally non-splashing water jet there. It has also created aerator, which aerate the escaping water steel and mixing the water flowing through it with the ambient air.

Thus, from DE 30 00 799 AI already a ventilated jet regulator already known in its jet regulator housing has a perforated plate having a plurality of Durchflußlöchern, which are arranged in concentric hole circles on the perforated plate and which flows through the jet regulator housing water in a corresponding Divide the number of individual beams. Since the flow-through holes narrow the clear flow area in the area of the perforated plate, the water flowing through in the flow-through holes experiences an increase in speed, which causes a negative pressure on the outflow side of the perforated plate according to the Bernoulli equation. By the negative pressure generated on the downstream side of the perforated plate ambient air is sucked in, provided by provided in the housing wall ventilation openings penetrate into the housing interior of the jet regulator housing and can be mixed there with the water flowing through. Thus, the water flowing through the plate is quietly divided into individual jets, among other things provided in DE 30 00 799 AI jet regulator, among other things, that the Durchflußlöcher have a polygonal cross-section hole section, which is followed by a cross-section increasingly extended and downstream cylindrical portion of the hole (See Figure 4 in DE 30 00 799 AI). Through such, different sections having flow holes in the flow holes in each case a cross-sectionally round ^' and linear outflowing single jet is generated. From EP 1 273 724 B1 (= DE 601 01 909 T2) is already known a jet regulator with a jet regulator housing, in whose housing interior a perforated plate is provided which has flow holes, which have a constant clear cross section in the flow direction. The perforated plate is followed by a baffle cone in the flow direction, which forms a constriction in the flow area of the previously known jet regulator. The individual beams generated in the perforated plate ^" can tear the ambient air in the housing interior of the jet regulator housing with it and then meet on the inclined surface ■ of the impact cone on that the aerated individual jets are broken up and mixed with the entrained air.

However, the prior art jet regulators require a certain flow and a sufficient water pressure in the pipeline network, so that sufficient negative pressure is generated on the downstream side of serving as a jet separator perforated plate to ambient air into the housing interior of the Strahlreg-. lergehäuses to suck. In contrast, the negative pressure formed at low flow and low water pressures is usually not sufficient to be able to ^: mix ambient air with the water flowing through.

It is therefore an object to provide a jet regulator of the type mentioned, which is able to produce a sufficiently ventilated and correspondingly pearly-soft water jet even at low flow and / or low water pressures, as they are often sought, for example, for water saving purposes , In this case, the generation of a possible voluminous beam is sought, which does not differ visually and haptically from the usual state of the art for the user, the jet regulator according to the invention should preferably be interchangeable with the known jet regulator designs. ^"

The solution to this problem in the jet regulator of the type mentioned in particular consists in the fact that at least one through-hole widens conically or conically towards its downstream side.

The jet regulator according to the invention has a jet regulator housing, in the housing interior of which a perforated plate extending, for example, over the housing cross-section is provided. The perforated plate has a plurality of flow holes, which are intended for dividing the water flowing through. At least one of the flow holes provided in the perforated plate widens increasingly conically or conically towards its downstream side and preferably as far as the downstream side. Due to the conical or conical spreading of the water emerging from the perforated plate, this can be practical even at low flow rates and low water pressures mix over the entire housing cross-section of the jet regulator housing with the ambient air sucked into the jet regulator housing. In this case, the good air mixing of the water flowing through is favored even at low flow rates and low water pressures, if at least one flow hole to such a conical or conical widened to its downstream side, that emerging from the flow hole and by the conical shape or conicity widening single beam itself in the housing interior even before the impingement of individual jets on at least one disposed in the housing interior beam molding with the single beam at least one adjacent Durchflußloches mixed.

In addition to or instead of the conical or conical widening design of at least one flow hole, another proposal according to the invention of its own worthy of protection in the jet regulator of the type mentioned above, that on the downstream side of the perforated plate in the jet regulator housing and / or ^: at the Abströmstirnfläche the jet regulator housing Flow obstacles are provided, which are arranged or concentrated there in a central or central region and deflect the water flowing through into an outer annular zone, in contrast, has no or a smaller number or total area of flow obstacles. In order to create the jet regulator with a jet regulator housing which corresponds in size to the dimensions of commercially available jet regulators for compatibility reasons and nevertheless to form a water jet which appears comparably voluminous in cross-section even at low flow rates, the water flowing through it is deflected by means of flow obstructions from a central or Central area at least partially deflected into an outer ring zone, which forms the outer periphery of the exiting water jet.

An advantageous embodiment according to the invention provides that on the downstream side of the perforated plate at a distance from this on the housing inner circumference a circumferential baffle slope is provided, which increasingly narrows the clear housing cross-section in this area in the flow direction. In this advantageous embodiment, the shape of the flow holes exiting and already enriched with air water strikes at a distance after the perforated plate on a baffle slope, which additionally mixes and divides the already so prepared water before the water enriched with air as homogeneous, not -springing and pearly-soft water jet can escape from the jet regulator.

A particularly easy to manufacture embodiment according to the invention provides that the baffle slope forms the inflow side of a Wandungsabschnitts, which is configured as at least one wavy constriction in longitudinal section.

In this case, the impact bevel can be designed as an inner peripheral side projection or inner peripheral side projection of the housing peripheral wall and can be integrally connected to the jet regulator housing or a jet regulator housing part.

However, an embodiment in which the baffle slope is formed as a wall portion of an insertable into the jet regulator housing annular or sleeve-shaped insert is preferred.

In order to use at least one beam molding in the housing interior of the jet regulator housing, even if the as It is advantageous if the jet regulator housing is designed in several parts and has at least two, preferably releasably connectable, housing parts.

In this case, particularly advantageous embodiments according to the invention, provide that the impact bevel is integrally formed on the housing inner circumference of a downstream housing part and / or that the perforated plate is integrally formed in the housing interior of an inflow-side housing part.

In addition to or preferably instead of a baffle slope, the perforated plate can be connected downstream of at least one mesh or lattice structure in the flow direction. The tapered or conically emerging from the flow holes and impinging on the at least one network or lattice water is braked there and decomposed with the adjacent disassembled portions of emerging from the adjacent flow holes water to then emerge as a soft overall beam from the jet regulator can.

 Although such a lattice structure can also be formed by an inserted metal mesh, which is formed from two sets of preferably rectangularly interwoven metal wires, - preferred is an embodiment in which the network or lattice structure of two flocks, at intersection nodes intersecting webs is formed. Such a network or lattice structure, which is formed from two flocks, at crossing nodes intersecting webs, can be produced in a simple manner as a plastic injection molded part.

In this case, a preferred embodiment according to the invention provides that the at least one, the perforated plate in Strö- mung direction downstream network structure of radial webs and thus crossing at crossing nodes concentric webs is formed. In order to further promote the decomposition of the water coming from the perforated plate, it may be advantageous if the perforated plate is followed in the direction of flow by at least two network or grid structures spaced apart from one another. In this case, a preferred development according to the invention provides that at least one flow hole in the flow direction is aligned with a radial web of a network structure and with a concentric web of an adjacent network structure. The divided in the perforated plate water flows out of the flow holes of the perforated plate less than single jet and rather than spray cone. In order to further break up and divide the spray cones emerging from the flow holes, it is advantageous if the webs each aligned with a flow hole overlap or intersect in the flow direction of the at least one flow hole in the various planes of these mesh or grid structures.

In order to be able to produce the jet regulator according to the invention with comparatively little outlay, for example, from individual plastic parts, it may be advantageous if each grid or lattice structure is formed by an insertable part which can be inserted into the housing interior of the jet regulator housing. In this case, a preferred embodiment provides that each insert part has on the outer peripheral side a circumferential annular wall, to which webs of the mesh or grid structure are held and preferably integrally formed. The breaking and dividing the emerging from the flow holes of the perforated plate spray cone is further promoted when at least the concentric ribs and preferably also the radial webs in a front direction of flow network structure in comparison to ^_the:; Webs of a downstream in the flow direction adjacent network structure has a same or smaller web thickness. The flow holes provided in the perforated plate can be arranged on concentric hole circles. However, a preferred embodiment according to the invention provides that the perforated plate has a central hole-free baffle which bounds at least one annular wall, that the at least one annular wall has radially oriented passage openings, and that on the arranged in the baffle plane side of the flow openings in each case a Durchflußloch the perforated plate is provided. The deflected in this way in the region of the ring wall water is first braked, deflected to the side and mixed by optionally in opposite directions to each other inflowing streams before flowing through the through holes of the perforated plate and on the downstream side of the perforated plate in the form of a corresponding number of Sprühkegeln can escape.

In order to reshape in the housing interior of the jet regulator housing with ambient air and correspondingly fluidized water on the outflow side of the jet regulator back to a homogeneous overall jet and to be able to shape the emerging from the jet regulator water in a downstream homogenizer to a non-squirting emerging water jet, it is expedient if the outflow-side end face of the jet regulator housing by a net or The honeycomb cell structure is formed, and if the net or honeycomb cell structure forming the outflow-side end face is either inseparably connected to the jet regulator housing and in particular integrally formed or formed by an insert which can be inserted into the jet regulator housing.

The equalization of the total jet emerging from the jet regulator is further promoted if the mesh or honeycomb cell structure forming the downstream end face of the jet regulator housing is formed by webs which taper in the flow direction at least in an outflow-side partial region.

A preferred embodiment according to the invention provides that the jet regulator according to the invention is designed as a ventilated jet regulator, in whose housing interior at least one ventilation opening opens, which connects the housing interior with the atmosphere. In order for the at least one ventilation opening to be able to connect the interior of the housing to the atmosphere, at least one ventilation channel can be provided in a double-walled section of the jet regulator housing or in an annular gap surrounding the jet regulator housing, which is designed to be open towards the atmosphere. Further developments according to the invention will become apparent from the claims in conjunction with the figures and the description of the figures. Hereinafter, the present invention will be described in more detail with reference to preferred embodiments.

It shows:

Fig. 1 a, in a perspective part -Längsschnitt shown jet regulator, which carries on the outer circumference of its jet regulator housing an external thread with which the jet regulator can be detachably screwed into an internal thread on the water outlet of a sanitary outlet fitting, the jet regulator of Figure 1 in a longitudinal section, wherein in the housing interior of the jet regulator housing integrally connected to an inflow-side housing part Perforated plate which carries flow holes, which extend conically or conically to the downstream side of the perforated plate, the jet regulator of Figure 1 and 2 in a longitudinal section through sectional plane III -III of Figure 2, wherein through the Durchflußlöcher the cross-cut perforated plate and the A detailed view of the cross-sectional representation shown in Figure 3 in the region of a ^: Durchflußloches the cross-cut perforated plate, the jet regulator of Figure 1 to 4 in an exploded perspective E Inzelteildarstellung, one, with the jet regulator of Figure 1 to 5 comparably designed jet regulator, wherein the jet regulator shown in Figure 6 by means of an outlet nozzle not shown here at the water outlet of a sanitary outlet fitting is mountable: and wherein the downstream end face FIG. 7 shows the inflow-side view of a further jet regulator, wherein this inflow-side view above all shows an attachment or filter screen arranged upstream of the jet regulator on the upstream side FIG. 8 shows the jet regulator of FIG. 7 in a longitudinal section through sectional plane VIII-VIII of FIG. 7, wherein it can be seen that the jet shown in FIG. 8 has a baffle slope spaced from the outflow side of the perforated plate clear flow cross-section of the jet regulator forms constricting constriction in the flow direction,

9 shows the perforated plate of the jet regulator shown in FIGS. 7 and 8 in a perspective partial longitudinal section,

10 is the downstream end face of the jet regulator shown in FIGS. 7 to 9 in a bottom view, FIG.

11 shows ^the. Steel regulator according to Figures 7 to 10 x is an exploded perspective exploded view,

12 shows the jet regulator from FIGS. 7 to 11 in an enlarged longitudinal section, wherein the flow direction of the water flowing through the jet regulator is indicated by corresponding arrows, and FIG

Fig. 13, the perforated plate of the shown in Figures 7 to 12 Beam regulator in an enlarged perspective partial longitudinal section.

FIGS. 1 to 13 show three exemplary embodiments 1, 10, 100 of a jet regulator. The jet regulator designs 1, 10, 100 are intended to be mounted on the water outlet of a sanitary outlet fitting in order to form a homogeneous and laterally non-splashing water jet there. In order to allow the jet of water to emerge as a pearly-soft water jet, the jet regulator designs 1, 10, 100 are designed as aerated jet regulators, in which the water flowing through is mixed with ambient air and enriched. ^The jet regulator embodiments 1, 10, 100 have a sleeve-shaped and round in cross-section flow regulator housing. 2 The jet regulator embodiment 1 shown in FIGS. 1 to 5 has an outer thread 3 on the outer circumference of the outer housing of the jet regulator housing 2, which cooperates with an internal thread which is arranged on the inner peripheral side at the water outlet of the outlet fitting not shown here. In this case, the jet regulator embodiment 1 illustrated here can be screwed into the water outlet in such a way that the downstream end face of the jet regulator housing 2 is arranged practically in one plane with the downstream end edge of the outlet fitting.

In contrast, the jet regulator embodiments 10, 100 shown in FIGS. 6 to 13 are to be mounted with a sleeve-shaped outlet mouthpiece at the water outlet of the outlet fitting, after the jet regulator 10, 100 has been inserted from the inflow-side sleeve opening of the outlet mouthpiece into its sleeve interior Ring paragraph 4 on the outer circumference of the jet regulator housing 2 a bearing in the outlet mouthpiece inner peripheral side bearing rests.

In the housing interior of the jet regulators 1, 10, 100, a perforated plate 5 is provided, which carries a plurality of Durchflußlöchern 6. At least one through-hole 6 and preferably all through-holes 6 of the perforated plate 5 extend conically or conically at least in an outflow-side partial region to their downstream side. The provided in the perforated plate 5 through holes 6 are intended for dividing the water flowing through. Due to the conical or conical spreading of the water emerging from the perforated plate, it can mix with the ambient air sucked into the jet regulator housing, even at low flow rates and low water pressures practically over the entire cross section of the jet regulator housing 2.

The flow holes 6 extend conically or conically in such a way that the water jet emerging from the flow holes 6 and widening due to the conical shape or conicity becomes at least one adjacent one in the interior of the housing prior to the impact of individual jets on at least one beam molding arranged in the interior of the housing Durchflußloches mixed.

In order to additionally divide the flowing water and to be able to mix with ambient air, at least one and preferably at least two network structures are connected downstream of the perforated plate 2 in the flow direction in the jet regulator embodiments 1, 10 shown in FIGS Webs 7 and thus crossing nodes 8 concentric webs 9 are formed. In FIGS. 3 and 4, it can be seen by way of example that at least one throughflow hole 6 and preferably all throughflow holes 6 are arranged in the flow direction with a radial web 7 of a network structure and here the network structure connected downstream in the flow direction and with a concentric web 9 of an adjacent one and here aligned on the inflow side network structure. The respectively aligned with one of the through-holes 6 webs 7, 9 cover or intersect here in a central or central region of the associated Durchflußloches 6 in the various levels of these network structures.

It is clear from a comparison of FIGS. 2, 5 and 6 that each of the network structures forming a beam regulation device is formed by an insertion part 11, 12 which can be inserted into the housing interior of the jet regulator housing 2. Each of these insert parts 11, 12 on the outer circumference has a peripheral annular wall 13, to which the radial webs 7 of the network structure, which intersect with the concentric webs 9, are connected in one piece.

FIG. 4 shows particularly clearly that at least the concentric webs 9 and preferably also the radial webs 7 of a network structure in front in the direction of flow have a greater web thickness in comparison to the webs 9, 7 of a network structure adjacent downstream. In this way, each flow hole 6 in the perforated plate 5 in the flow direction appears to divide into a plurality of further smaller flow openings.

It can be seen from a comparison of FIGS. 2, 5, 6, 8 and 9 that the perforated plates 2 provided in the aerator embodiments 1, 10, 100 have a central baffle surface 14, which is bounded by at least one annular wall 15. This annular wall 15 has oriented in the radial direction through openings 16, which are spaced apart here over the circumference of the annular wall 15 from each other. On the bottom side and thus on the arranged in the baffle plane side of the passage openings 16 each one of the through holes 6 of the perforated plate 2 is provided. By this deflection of the inflowing water in the region of the flow holes 6, the water is braked, deflected to the side and optionally mixed by, in opposite directions inflowing part streams to then experience as a result of the narrowing of the flow in the flow holes 6 again an increase in speed. According to the Bernoulli equation, a vacuum is generated by this increase in speed on the outflow side of the perforated plate 5, by means of which ambient air into the housing interior of the

Radiation controller housing 2 can be sucked. In the housing circumferential wall of the jet regulator housing 2, at least one ventilation opening 17 which opens out on the outflow side of the perforated plate 5 in the interior of the housing is provided for this purpose. Beyond the central baffle surface 14, at least one further baffle surface 29, which circulates on the outside, may be provided, which is preferably arranged in the plane of the central baffle surface 14.

While the at least one ventilation opening 17 in the jet regulator embodiment 1 shown in FIGS. 1 to 5 here is connected to the atmosphere via a double-walled section 18 of the housing peripheral wall on the outflow side of the jet regulator 1, the jet regulator embodiments 10 shown in FIGS 100, the ventilation openings 17, the jet regulator housing 2 in the radial direction and are on the outside of the jet regulator housing 2 with a Connected ventilation duct, which is formed as an annular gap between the housing outer circumference of the jet regulator housing 2 and the inner circumference of the outlet mouthpiece and which is open to the downstream end face of outlet nozzle and jet regulator 10, 100 to the atmosphere.

Instead of the insert parts 11, 12, the jet regulator embodiment 100 shown in Figure 7 to 13 on the downstream side of the perforated plate 2 at a distance from this on the inner circumference of the housing a circumferential baffle 19, which increasingly narrows the clear housing cross section in this area in the flow direction. This baffle slope 19 is formed by the inflow side of a wall section designed as a wavy constriction in longitudinal section. The wall section having the baffle slope 19 is here as a ^: into the jet regulator housing 2; usable annular or sleeve-shaped insert 20 designed.

From a comparison of Figures 6 and 11 on the one hand and Figure 5 on the other hand it is clear that the downstream end face of the jet regulator 1, 10, 100 is formed by a network structure 22 or a honeycomb cell structure 21. While the network or honeycomb cell structure 22, 21 forming the outflow-side end face of the jet regulators 1, 100 is permanently connected to the jet regulator housing 2, the outlet structure 22 of the jet regulator 10 shown in FIG. 6 is formed by an insert part 23 which can be inserted into the jet regulator housing 2. It can be seen from a comparison of FIGS. 8 and 10 that the network structure 22 forming the outflow-side end face of the jet regulator 100 is formed by radial and concentric webs 24, 25, which taper in the flow direction at least in a downstream region. Since these webs 24, 25 at least in a In the flow-side partial region tapering in the flow direction, homogenization and homogenization of the water emerging from the jet regulator housing 2 through the network structure is additionally promoted in the form of a homogeneous overall jet.

In FIGS. 10 and 11 it becomes clear that on the outflow side of the perforated plate in the jet regulator housing and / or - as here at the outflow end face of the jet regulator housing 2 flow obstacles can be provided, which are arranged or concentrated there in a central or central area and which flows through the Redirecting water into an outer annular zone, which in contrast has no or a smaller number or total area of flow obstacles. In the case of the jet regulator 100 shown in FIGS. 10 and 11, these flow obstacles are formed by the concentric webs 25 which are located at the outflow end surface of the jet

Radiation regulator housing 2 are concentrated to a central or central area, while an outer annular zone is free of such concentric webs.

In FIGS. 5, 6 and 11, it is clear that the jet regulator housing 2 is formed here by two housing parts 26, 27, which are detachably connectable and preferably latchable to each other, of which the front housing part 26 on the inflow side is integrally connected to the perforated plate 6 , So that the dirt particles possibly entrained in the water can not impair the proper functioning of the jet regulator, the jet regulator housing 2 is preceded by an attachment or filter screen 28, which is held detachably on the inflow-side housing part 26 here. This attachment or filter screen 28 has a multiplicity of round or rectangular, in particular hexagonal, filter or sieve openings.

/ LIST OF REFERENCE NUMBERS Reference sign list

I jet regulator (according to FIGS. 1 to 5)

2 aerator housing

 3 external threads

 4 ring heel

 5 perforated plate

 6 flow holes (in the perforated plate 5)

7 (radial) webs

 8 crossing nodes

 9 (concentric) footbridges

 10 jet regulator (according to FIG. 6)

 II (inflow-side) insert part

12 (downstream) insert part

 13 ring wall (on the insert parts 11, 12)

 14 baffle (centrally on the perforated plate 5)

 15 ring wall (on the inflow side on the perforated plate 5)

 16 passages (in the ring wall 15)

17 ventilation opening (in the jet regulator housing 2)

 18 (double-walled) section (the housing peripheral wall)

19 baffle slope

 20 insert part (with baffle slope 19)

 21 honeycomb cell structure (as the downstream end face of the .Radir controller);

 22 Network structure (as a downstream end face of the jet regulator)

 23 insert (as a downstream end face of the steel regulator 10)

24 (radial) webs (the downstream end face of the jet regulator 100)

25 (concentric) webs (at the downstream end face of the jet regulator 100) (upstream) housing part

(downstream) housing part

Attachment or filter screen

(outside circumferential) baffle (the perforated plate 5) jet regulator (according to the figures 7 to 13)

Claims

claims

Jet regulator (1, 10, 100) with a jet regulator housing (2), in the housing interior of a perforated plate (5) is provided with a plurality of flow holes (6) for dividing the water flowing through, characterized in that at least one flow hole (6) widened conically or conically at least in a downstream-side hole section to its downstream side.

A jet regulator according to claim 1, characterized in that at least one flow hole (6) widens conically or conically at least in an outflow side hole section towards its downstream side so as to emerge from the flow hole (6) and form the cone or taper expanding single jet or spray in the housing interior preferably before the impact of individual jets on at least one arranged in the housing interior beam molding with the single steel at least one adjacent flow hole (6) mixed.

Flow regulator (100) according to the preamble of claim 1, particularly according to claim 1 or 2, characterized in that on the downstream side of the perforated plate (5) in the flow regulator housing (2) and / or on the Abströmstirnfläche the jet regulator housing ^(2): flow obstacles are provided which are arranged or concentrated there in a central or central area and divert the water flowing through into an outer ring zone.

Jet regulator according to one of claims 1 to 3, characterized characterized in that on the downstream side of the perforated plate (5) at a distance from this a circumferential baffle slope (19) is provided, which increasingly narrows the clear Gehauseguerschnitt in this area in the flow direction.

Jet regulator according to claim 4, characterized in that the baffle slope (19) forms the inflow side of a Wandungsabschnitts, which is formed as at least one wavy constriction in longitudinal section.

Flow regulator according to one of claims 1 to 5, characterized in that the jet regulator housing (2) is designed in several parts and has at least two, preferably releasably connectable housing parts (26, 27).

Jet regulator according to one of claims 4 to 6, characterized in that the baffle slopes (19) on the housing inner circumference of a downstream housing part (27) is integrally formed and / or that the perforated plate (5) in the housing interior of an inflow-side housing part (26) in one piece is formed.

Jet regulator according to one of claims 1 to 7, characterized in that the perforated plate (5) in the flow direction at least one network or grid structure is connected downstream.

Jet regulator according to claim 8, characterized in that the network or lattice structure of two shares, at crossing nodes (8) intersecting webs (7, 9) is formed.

Jet regulator according to claim 9, characterized in that the network structure of radial webs (7) and thus to Junction node (8) crossing concentric webs (9) is formed.

Jet regulator according to one of claims 8 to 10, characterized in that the perforated plate (5) in the flow direction at least two spaced-apart mesh or grid structures are connected downstream.

Jet regulator according to claim 10 or 11, characterized in that at least one flow hole (6) in the flow direction with a radial web (7) of a network structure and with a concentric web (9) of an adjacent network structure is aligned.

Jet regulator according to one of claims 10 to 12, characterized in that each with a flow hole (6) aligned webs (7, 8) overlap or intersect in the flow direction of the at least one Durchflußloches (6) in the different levels of these network structures.

Jet regulator according to one of claims 10 to 13, characterized in that each network structure is formed by an insertable part (11, 12) insertable into the housing interior of the jet regulator housing (2).

Flow regulator neighboring one of ^"claims 9 to 14, characterized in that each insert (11, 12) outer circumference side, a circumferential annular wall (13), connected to which webs (7) of the net or lattice structure and preferably formed in one piece are ,

Jet regulator according to one of claims 10 to 15, characterized in that at least the concentric webs (9) and preferably also the radial webs (7) of a front in the flow direction network structure in comparison to the webs (7, 9) of a downstream in the flow direction ig adjacent network structure have a same or smaller web thickness.

Jet regulator according to one of claims 1 to 16, characterized in that ^: the perforated plate (5) has a central hole-free baffle surface (14) which delimits at least one annular wall (15) such that the annular wall (15) has passage openings (16) oriented in the radial direction ), and that in each case one through-flow hole (6) of the perforated plate (5) is provided on the side of the passage openings (16) arranged in the baffle plane.

Jet regulator: according to claim 17, characterized in that the annular wall (15) is bounded on the outer peripheral side by a preferably annular circumferential baffle surface (29).

Flow regulator according to one of claims 1 to 18, characterized in that the outflow-side end face of the jet regulator housing (2) through a network or a honeycomb cell structure (21; 22) is formed and that the downstream end face forming network or Wabenzel ^¬ lenstruktur (21 22) either inseparably connected to the jet regulator housing (2) and, in particular, integrally formed or formed by an insert (23) which can be inserted into the jet regulator housing (2).

Flow regulator according to claim 19, characterized in that the downstream end face of the Strahlreg ^¬ lergehäuses (2) forming net or honeycomb cell structure (21; 22) by webs (24, 25) is formed, which taper at least in an outflow-side portion in the flow direction. 21. jet regulator according to one of claims 1 to 20, characterized in that the jet regulator (1, 10, 100) is designed as a ventilated Strählregler having at least one ventilation opening (17) on the outflow side of the perforated plate (5) in the housing interior opens and connects the interior of the housing with the atmosphere.