DE102009019932A1 - Deflector for nozzle unit of e.g. circle sprinkler, for automatic watering of e.g. park, has grooves with radial expansion that ends in distance to outline edge, and transient area implemented between deflection surface and stop section - Google Patents

Abstract

The deflector (1) has a thread-like deflection surface (2) limited by low and high curvatures, so that a differential area is formed after circling of 360 degrees at junction point. A set of radially running grooves (3) are formed in the deflection surface toward an outline edge (4), and include flanks (10) that are rounded in a transition to the deflection surface. The grooves comprise radial expansion that ends in a distance to the outline edge. A transient area is implemented between the deflection surface and a stop section (20) with a radius.

Description

The The invention relates to a deflector for a nozzle unit a sprinkler, in particular for a circular sprinkler with variable adjustable irrigation area, according to the preamble of claim 1

Regarding the automatic irrigation of parks and lawns sprinklers are often used. For this purpose, so-called circular sprinklers are known, which are able to irrigate their environment in an angular range of up to 360 °. The circular sprinklers typically have a fixed sprinkler base with channeling leading from a supply port to a water outlet. Here, a nozzle arrangement is generally provided upstream of the liquid outlet, which comprises a directed against a deflector nozzle unit with at least one jet nozzle. By means of this deflector, the liquid emanating from the jet nozzle is deflected for irrigation in the environment adjacent to the sprinkler, as for example in the patent specification US 4 579 285 A described. Often, in this case, the nozzle unit is designed such that the angular range of the sprinkled sector can be variably limited.

A nozzle unit for a circular sprinkler with variable limitation of the sprinkling area, for example, from the German utility model DE 20 2007 014 407 U1 or the German patent DE 600 03 600 T2 known. These sprinklers have a deflector mounted above a main body, which is provided on its surface with a thread-like or arcuate shaped deflecting surface. The deflection surface is bounded here by a high and a low arcuate line, so that after forming a 360 ° orbit at a connection point, a differential surface forms, which forms a substantially radially extending abutment portion. The surface of the main body opposite the deflecting surface of the deflector has a surface which is adapted to the shape of the deflecting surface and which likewise has a radially extending abutment portion. By means of a rotating mechanism of the deflector and the main body can be rotated against each other, so that the stopper portions can be adjusted in any angular positions to each other. The positions of the abutment portions then define the angular extent of the environmental region sprayed by the circular sprinkler, since the abutment portions limit the flow of water on the deflection surface of the deflector. Due to its flow against the stop sections, the liquid distributed by the sprinkler in these areas has a spray pattern that significantly distorts the irrigation pattern. It also turns out that the characteristic of this piercing beam varies with the position of the two stop sections relative to one another and is thus difficult to predict.

In order to be able to convey the liquid sprayed by the circular sprinklers in a more targeted manner to the individual angle sections of the angular area which is sprayed in total, the patent documents, for example, disclose US 4,739,934 A and US 5 556 036 A proposed to provide the surfaces of the deflector with a plurality of radially extending to the trailing edge of the deflector fins. As a result, the fluid to be distributed even then quite accurately fed to the individual angle sectors, if the liquid jet impinges obliquely on the deflector, for example due to the formation of the nozzle or if due to the geometry of the surface of the deflector, the liquid would be derived obliquely, which is often with helical surface geometry is the case.

Alternatively to the formation of lamellar structures for targeted beam steering, it is from the patents US 4,184,239 A and US Pat. No. 4,625,917 or the German Offenlegungsschrift DE 196 34 332 A1 known to introduce in the surface of the deflector from the trailing edge radially inwardly extending grooves. Although both the lamellar and the groove structures largely avoid that the inflowing liquid to the deflector is deflected in undesirable angular ranges, but show the disadvantage of a jet-shaped fanning of the desired uniform angle independent irrigation image.

task The invention is a deflector for a nozzle unit to create a sprinkler, which one over a large one Angular range even and well adjustable Irrigation picture creates.

The Invention is provided with a deflector for a nozzle unit a sprinkler with the features of claim 1 solved. Herein are described three alternative embodiments, each of which single by itself already solves the task, in but in their entirety to an optimal task solution leads. Advantageous embodiments and developments The invention will be described with the subclaims.

The deflector is suitable for the nozzle unit of a sprinkler, which has a supply port, a liquid outlet and a channeling leading from the supply port to the liquid outlet, wherein upstream of the liquid outlet is a nozzle assembly with at least one jet nozzle which is directed against the deflector. Here, on the side facing the jet nozzle of the deflector a formed thread-shaped or arcuate deflection surface, which is delimited by low and high arc lines, so that forms after a 360 degree orbiting at a junction a differential surface, which forms a substantially radially extending abutment portion. The low arc line on the deflector forms a trailing edge, which is aligned substantially perpendicular with respect to the discharge direction of the jet nozzle.

In a first possible embodiment of the invention in the deflecting surface of the deflector in the direction of the spoiler edge formed radially extending grooves whose flanks in their transition have rounded flanks to the surface of the deflection. As a result, the liquid distribution is only moderate channeled. This has the advantage that while an undesirable Angular deflection of the liquid caused by oblique Impact on the deflector or as a result of its winding surface, is counteracted over the entire angular range desired uniform jet image only is minimally influenced.

In a second alternative embodiment of the invention end the in the deflecting surface of the deflector in the direction of the spoiler edge radially extending grooves at a distance AB to the trailing edge. Thus, although the channels in the deflection surface channel a part the liquid to be deflected, but this is before Distribution into the irrigation area above the even Guided edge area of the deflection. In this way become the dominating single rays resulting from the canalization largely expanded. As this even edge area only a small portion of the total deflection area, can here any still occurring angular deflection of the liquid neglected due to the winding course of the surface become.

In the third alternative embodiment of the invention is in the Deflector, the transition region between the deflection and the abutment portion is radiused. This will cause a direct transition of the deflection surface avoided in the stopper section formed thereon, so that that of the inflowing liquid vertically forces acting on the abutment portion are reduced. This leads to a substantial reduction of the Counterforce resulting piercing beam and thus serves the harmonization of the irrigation sprayed by the sprinkler.

profitably the deflector according to the invention is then optimal in terms of creating a well-adjustable and even Sprung image configured if two or all of the invention alternative Embodiments are combined with each other, as these alternatives complement each other synergistically, without a coordinated one Adaptation of the individual aspects is necessary.

In Advantageously, it is conceivable, the flanks of the grooves along their radial course toward the trailing edge increasingly further spaced this reduces the unwanted, resulting from the channeling fanning of the liquid in individual beams even further. In the event that the grooves are not be guided completely to the spoiler lip of the deflector, results in the expansion of the grooves towards the even Edge surface of the deflection in a gentler transition and so to even further improved beam expansion.

Also It is very possible, the grooves in their expression to make such that their depth along their radial course towards the tear-off edge decreases. Complementary or alternative to a widening of the grooves also leads this configuration to a profitable expansion of the individual beams and contributes thus contributing to a uniform jet pattern.

For the case that the grooves with one in the direction of the tear-off edge the deflector's decreasing depth profile are executed it offers itself in a particularly advantageous manner, the depth course in Direction of the trailing edge in at least two sections different Split slope. This should be the first of the trailing edge furthest spaced section no or a respect the other sections has lower slope. hereby In particular, it becomes possible relative to the tear-off edge to realize rapid decrease in depth, without facing away from the tear-off edge To finish the groove too deep, what to do possibly the need for a thicker version could cause the wall thickness of the deflector.

In Particularly advantageously, the deflection surface is so further developed that the profile of the stopper portion at least two angularly offset and radially spaced line sections arranged wherein only the transition region between the deflection surface and the line region adjacent to the trailing edge with a radius is provided. In this way, the on the rear line section inflowing liquid clearly in radial Direction directed towards the trailing edge of the deflection and so does one through the radiused transition area possibly caused unwanted angular deflection of the entire Fluid jet opposite.

Such an undesirable deflection can be further counteracted if, in an advantageous manner, connecting the line segments Connecting portion to the radius of the deflection surface is formed at an angle less than 90 degrees. As a result of this, the part beam which is directed strongly radially at the region of the abutment portion which is further away from the tear-off edge is even better superimposed on the other, less directed partial beam.

following the invention with reference to an advantageous embodiment with the help explained in detail by figures. It shows

1 a cross section through the body of the deflector 1 ;

2 a plan view of the deflection surface 2 of the deflector 1 out 1 ;

3 a section along a line AA through one with grooves 3 provided, the stopper section 20 having area of the deflection surface 2 of the deflector 1 ;

4 a detailed view of a portion of the deflection surface 2 of the deflector 1 in the area of the stop section 20 ,

The 1 shows an advantageous embodiment of the deflector according to the invention 1 with a deflection surface lying in the direction of flow S of the liquid flowing out of a nozzle arrangement of a sprinkler 2 , In a preferred embodiment, the deflection surface closes 2 to the longitudinal axis L of the deflector 1 an angle of 75 degrees. In the deflection area 2 are here radially extending grooves 3 provided, which at a distance AB from the deflection surface 2 limiting spoiler lip 4 end away. This shows that by the on the deflection surface 2 located grooves 3 The effect of the liquid bundling effected is all the more the greater the distance AB is selected.

In the illustrated preferred embodiment, the grooves are 3 designed so that its depth decreases along its radial course towards the trailing edge. In particular, the depth profile of the grooves 3 in the advantageous embodiment shown here chosen so that it in two areas 5a and 5b divided by different pitch. In this case, that of the spoiler edge 4 furthest spaced area 5b no gradient up. To the liquid from the deflection surface 2 should be transferred optimally into the surrounding area of the sprinkler, which should be at the deflection surface 2 trained tear-off edge 4 be executed as sharp as possible.

The 2 shows a plan view of the deflection surface 2 of the deflector 1 out 1 , Along the circumference of the deflector 1 are a plurality of formations 6 provided by which a better grip is given in the manual rotation of the deflector. The through the tear-off edge 4 limited deflection surface is provided with a plurality of radially arranged grooves 3 Mistake. The flanks 10 . 11 the grooves 3 They are designed so that they go with their course towards the trailing edge 4 increasingly spaced apart. In addition, the flanks 10 . 11 rounded in their transition to the deflection surface, in particular from the cross-sectional view in the 3 becomes clear.

The 3 shows a section along a line AA through one with grooves 3 provided, a stopper section 20 having area of the deflection surface 2 of the deflector 1 , The sectional image becomes the rounding of the flanks 10 . 11 the grooves 3 seen. Also, the one with a radius 21 provided transition between the deflection surface 2 and the stopper section 20 clearly.

Like from the 4 can be seen in the deflector shown here, which combines all three alternative inventive embodiments synergistically in a profitable manner, the stopper portion 20 in two angularly offset and radially spaced line sections 22 and 23 divided up. Only the transition of the deflection surface 2 to the section edge 4 closest line section 22 is provided with a radius R The two line sections 22 and 23 are over a connecting section 24 ver together, which to the radius AR of the deflection 2 has an angle less than 90 degrees.

In particular, the invention is suitable for use in a spray nozzle as for example with the protection claims of the utility model DE 20 2007 014 407 U1 is described in which the cover body described there, also having a thread-like deflection surface having the deflector according to the invention is replaced.

The spray nozzle described in this utility model has a main portion in which a hollow threaded portion is formed. The lower end of the threaded portion is provided with an axially extending annular groove. According to the cover body described there, can advantageously also the deflector according to the invention 1 with a round neck arranged at the lower end 10 be formed, as a threaded body 11 is formed and can be screwed into the fetch threaded body of the main section. Preferably, the lower portion of the round neck 10 a radial groove 13 on, resulting in two symmetrically arranged to each other, half arc sections. In a special way is at the lower end of the deflector 1 in addition an annular rib 12 trained, who like 1 obviously has a larger diameter. To the introduction of the deflector 1 in the main section of the spray nozzle is by the axial insertion of a threaded bolt in the radial direction of the round neck 10 in the area of the ring rib 12 so far expands that they can move in the formed in the threaded portion annular groove.

From experiments it is known that the against the stop section 20 flowing liquid is not ideal from the deflection surface 2 is sprayed radially directly into the vicinity of the sprinkler, but is partially deflected in a rich direction A, which with the radius AR of the deflection 2 includes an angle. This has the consequence that the sprinkler is then already a completely surrounding sprinkler image results when the deflector 1 has not yet been completely rotated 360 degrees relative to the main section of the spray nozzle. In most cases, the fully enclosing sprinkling pattern already results at an angle adjustment of the deflector 1 after a rotation of about 355-358 degrees.

Will be the deflector 1 used in a spray nozzle, as for example from the utility model DE 20 2007 014 407 U1 is known, it lends itself to the deflector 1 trained ring rib 12 so on the round neck 10 To position these already before a complete rotation of the deflector 1 360 degrees against the upper end of the annular groove, which is formed on the threaded portion of the main body, preferably already after a rotation of about 355-358 degrees. In this way, a complete revolution of the deflector 1 is prevented by 360 degrees and thus ensures that the irrigation image has no overlap area in which undesirably much liquid is entered.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - US 4579285 A [0002]
• - DE 202007014407 U1 [0003, 0028, 0031]
• - DE 60003600 T2 [0003]
• US 4739934 A [0004]
• US 5556036 A [0004]
• - US 4184239 A [0005]
• US 4625917 [0005]
• - DE 19634332 A1 [0005]

Claims (8)

Deflector for a nozzle unit of a sprinkler, which is provided with a supply port, a liquid outlet and a channeling leading from the supply port to the liquid outlet and comprising a nozzle assembly located upstream of the liquid outlet with at least one jet nozzle which is against the deflector ( 1 ), wherein at the jet nozzle facing surface of the deflector ( 1 ) a thread-like deflection surface ( 2 ) is formed, which is delimited by low and high arc lines, so that after a 360 degree orbit at a connection point forms a differential surface, which has a substantially radially extending abutment portion ( 20 ), wherein the low arc line at the deflection surface ( 2 ) a tear-off edge ( 4 ) which is oriented substantially perpendicularly with respect to the outflow direction (S) of the jet nozzle, characterized in that in the deflection surface ( 2 ) in the direction of the trailing edge ( 4 ) radially extending grooves ( 3 ) are formed whose flanks ( 10 ) in their transition to the deflection surface ( 20 ) are rounded, and / or that in the deflection ( 2 ) in the direction of the trailing edge ( 4 ) radially extending grooves ( 3 ) are formed whose radial extent at a distance (A) to the trailing edge ( 4 ) ends, and / or the transition region between the deflection surface ( 2 ) and the stop section ( 20 ) is designed with a radius (R). Deflector according to claim 1, characterized in that the flanks of the grooves ( 3 ) along its radial course towards the trailing edge ( 4 ) are increasingly spaced apart. Deflector according to claim 1 or 2, characterized in that the depth of the grooves ( 3 ) along its radial course towards the trailing edge ( 4 ) decreases. Deflector according to claim 3, characterized in that the depth profile of the grooves ( 3 ) in the direction of the tear-off edge ( 4 ) at least two subsections ( 5a . 5b ) has a different pitch, where a first of the spoiler edge furthest spaced portion ( 5b ) none or one of the other subsections ( 5a ) has a lower slope. Deflector according to one of the claims 1 to 4 , characterized in that the profile of the abutment portion ( 20 ) at least two angularly offset and radially spaced line sections ( 22 . 23 ), wherein only the transition region between the deflection surface ( 2 ) and the line section adjacent to the trailing edge ( 22 ) is provided with a radius (R). Deflector according to claim 5, characterized in that the line segments ( 22 . 23 ) connecting section ( 24 ) to the radius (AR) of the deflection surface (FIG. 2 ) forms an angle smaller than 90 degrees. Deflector according to one of the preceding claims, characterized in that the lower end of the deflector 1 as a round neck 10 is formed, as a threaded body 11 is formed, wherein at the lower portion of the round neck 10 an annular rib 12 is trained. Deflector according to claim 7, characterized in that the lower portion of the round neck 10 a radial groove 13 having.