EP0762941B1 - Rotary nozzle for high pressure cleaning appliances - Google Patents

Description

The invention relates to a rotor nozzle for a high-pressure cleaning device with a housing that is in an end wall with a pan-shaped, centrally perforated depression is provided with a through hole having nozzle body, which is formed with a spherical Supports the end in the pan-shaped recess, extending longitudinally over part of the housing extends and has an outer diameter that is smaller is called the inside diameter of the case, and with a in one direction opening into the housing for the liquid through which the liquid in the housing is around the longitudinal axis is rotatable so that the Nozzle body rotates together with the rotating liquid and in doing so with a contact surface on its circumference bears against the inner wall of the housing, the Longitudinal axis of the nozzle body with respect to the longitudinal axis of the Housing is inclined being in the upstream portion of the through hole a rectifier with axially parallel and diametrical arranged in the through hole Walls is used.

Such a rotor nozzle is from DE-A-4 133 973 known.

Another rotor nozzle is from, for example DE-A-40 13 446 known. It has proven to be very effective Cleaning nozzle proved that with this nozzle one on one Conical shell encircling compact beam can be generated with which a larger area can be reached, while maintaining the properties of the compact beam stay.

This is also achieved with another known rotor nozzle, which, however, has a different drive principle, because in this known rotor nozzle, the nozzle body via a Turbine or a paddle wheel is driven (EP 0 379 654 B1). This is in the area of a central, axially parallel liquid supply, the liquid is not in total inside the case Offset, but the rotational movement of the Nozzle body results from the impact of the entering Liquid on the blades of the turbine. The one with it associated deflection of the liquid leads to a strong turbulence in the interior of the nozzle and thus too turbulent flow conditions. This in turn continues to the outlet area of the nozzle body, so that the cleaning effect is impaired by the turbulent flow can be.

It is an object of the invention at the beginning of a rotor nozzle described type an improvement in the cleaning effect to achieve.

This is the case with a rotor nozzle as described at the beginning Art solved according to the invention in that the length of the Through hole in the nozzle body is at least 70 mm, that the ratio of the length of the through hole for their diameter the value 17 or a larger value has and that the length of the rectifier is at least 0.25 the length of the through hole.

It has surprisingly turned out that the specified characteristics in combination with flow conditions in the nozzle body through which the cleaning effect is increased.

This is probably because the current in the Nozzle body with this special design very turbulence-free can be done so that from the nozzle body emerging beam very compact over a long distance stays and does not fan out. This is particularly the case turbulence-free flow once through the length, due to the large ratio of length to diameter and due to the great length of the rectifier used to others through the combination of these dimensions with the drive principle described, in which the Liquid in the rectifier rotates as a whole and not disrupted by turbine blades and their abrupt deflection becomes. Because the nozzle body of the rotating Liquid is taken along is the relative speed between circulating liquid on the one hand and circulating Nozzle body on the other hand at the inlet of the nozzle body low, so that in this area when the Liquid in the nozzle body has only minor flow disturbances be occurring. These remaining minor ones Flow disturbances can be caused by the special dimensioning the through hole and the rectifier be eliminated so far that one previously known Rotor nozzles not achievable cleaning effect achievable is.

It is advantageous if the diameter of the through hole with the exception of the outlet area is the same, if none in the through hole Steps or narrowing occur. It goes without saying in the outlet area, the through hole in the outlet opening an outlet nozzle, and this outlet opening usually has a much smaller diameter than the through hole. Again, it is beneficial if the transition from the through hole into the outlet opening the nozzle takes place continuously, as is known per se.

According to a preferred embodiment of the invention further provided that the thickness of the walls of the rectifier maximum 1/40 of the total length of the rectifier is. This is a very small wall thickness that goes with it leads the flow through the through hole the walls are minimally disturbed. This also promotes Uniformity of the flow through the through hole considerably.

It is advantageous if the rectifier is made of metal exists because of the higher strength values of Metal compared to plastic worked with smaller wall thicknesses can be done without damaging the rectifier and thus a change in the rectifier geometry to fear.

In a preferred embodiment can be provided be that the width of the walls of the rectifier over the most of its length is the inside diameter of the through hole corresponds to the walls at the upstream slightly widened end of the rectifier are and that the widened parts of the walls into one Penetrate insert made of deformable material upstream end of the through hole Forms inner wall. This makes it possible to use the rectifier through axial insertion into the through hole to set, since the widened ends of the Rectifier dig into the deformable material and thus fix the rectifier in this position. At the same time, the walls with most of them Split the length on the inner wall of the through hole and divide thus the through hole in axially parallel and complete separate channels leading to reassurance of the liquid.

It can be provided that in an expanded section at the upstream end of the through hole a plastic ring is used, the deformable Material forms.

In a preferred embodiment the rotor nozzle is provided that at the downstream end of the through hole a nozzle insert is arranged with an outlet opening is the outlet direction with respect to the longitudinal axis of the nozzle body is inclined.

Due to this inclination of the outlet opening with respect to the longitudinal axis the compact jet from the nozzle body No longer the nozzle body in the direction of the longitudinal axis of the nozzle body given, but obliquely to this longitudinal direction, that is, at an angle to this longitudinal direction inclined. This longitudinal direction of the nozzle body forms at the same time the axis of rotation, about which a self-rotation of the nozzle body in the housing is possible, so that by this self-rotation of the nozzle body about its own longitudinal axis also the direction of the outlet opening on a cone jacket revolves around a conical surface, the axis of which coincides with the longitudinal axis of the nozzle body. After this the nozzle body itself also on a cone jacket rotates, you get a complicated in this way Superimposition movement of the emitted compact beam, this first runs according to the conical Orbit of the nozzle body on a conical surface around, and according to the natural rotation of the nozzle body around the its own longitudinal axis is superimposed on this revolution a conical orbit of the beam, this time in Extension of the longitudinal direction of the nozzle body itself.

It is particularly advantageous in the present embodiment that that by connecting the specially dimensioned Through hole formed a very compact beam is through the outlet opening opposite the Longitudinal axis of the nozzle body is deflected and his maintains compact nature in full. So it works a very compact jet on a superimposed cone surface um, and this leads to the fact that when this compact beam on a surface a circular stripe very is effectively cleaned, since practically every point of the Circular streak hit by the very compact beam becomes.

It is advantageous if the inclination of the outlet opening small compared to the longitudinal axis of the nozzle body is, for example, on the order of 0.5 ° to 10 °, preferably from 1 ° to 5 ° and very preferably in the range between 2 ° and 3.5 °. A relatively small one is therefore sufficient Inclination of the outlet opening with respect to the axis of rotation of the nozzle body to achieve the desired effect.

In a first embodiment it can be provided that the nozzle body receives a nozzle insert in which one opposite the longitudinal axis of the axially parallel in the nozzle body fitted nozzle insert inclined outlet opening is.

In another embodiment, however, it is provided that the nozzle body has a nozzle insert with an axially parallel accommodates outlet opening arranged in the nozzle insert and that the nozzle insert in the nozzle body with its own Axis is arranged inclined relative to the longitudinal axis.

With these two solutions, either the nozzle insert is used even with one versus your own Longitudinal axis of the nozzle insert inclined outlet opening or a conventional nozzle insert with axially parallel The outlet opening is inserted at an angle into the nozzle body.

Figur 1:

eine Längsschnittansicht einer Rotordüse;

Figur 2:

eine Schnittansicht längs Linie 2-2 in Figur 1;

Figur 3:

eine vergrößerte Teilansicht des Auslaßbereichs der Rotordüse der Figur 1 bei einem abgewandelten Ausführungsbeispiel mit einem Düseneinsatz mit geneigter Auslaßöffnung und

Figur 4:

eine Ansicht ähnlich Figur 3 bei einem weiteren bevorzugten Ausführungsbeispiel mit einem Düseneinsatz mit achsparalleler Auslaßöffnung, der schräg in den Düsenkörper eingesetzt ist.

The following description of a preferred embodiment of the invention serves in conjunction with the drawing for a more detailed explanation. Show it:

Figure 1:

a longitudinal sectional view of a rotor nozzle;

Figure 2:

a sectional view taken along line 2-2 in Figure 1;

Figure 3:

an enlarged partial view of the outlet region of the rotor nozzle of Figure 1 in a modified embodiment with a nozzle insert with an inclined outlet opening and

Figure 4:

a view similar to Figure 3 in a further preferred embodiment with a nozzle insert with an axially parallel outlet opening, which is inserted obliquely in the nozzle body.

The rotor nozzle shown in the drawing includes one central screw connection 1, one in the drawing high-pressure line, not shown, are screwed in can, due to the cleaning liquid under high pressure is fed. The screw connection 1 opens into a central one Blind hole 2, which is essentially transverse to Longitudinal direction of the blind hole 2 extending tangential Bores 3 with the interior 4 of a housing 5 of the Rotor nozzle is connected. This housing 5 is formed through a hood-shaped housing cap 6, which on an external thread 7 of the screw connection 1 and the bottom hole 8 receiving the blind hole 2 is screwed on. Housing cap 6 and bottom part 8 are through an interposed ring seal 9 to the outside sealed. The bottom part 8 has a central to Interior 4 directed projection 10, the between himself and the inner wall of the interior 4 the blind hole 2 coaxial surrounding annular space 11 forms, in which open the holes 3 such that the from the Bores 3 in the annular space 11 entering liquid Annulus 11 is accelerated in the circumferential direction. This results in the laterally offset arrangement of the Bores 3 through which a tangential to the circumferential direction running component is introduced into the flow.

The side wall 12 delimiting the annular space 11 on the inside the projection 10 has an annular shoulder-shaped shoulder 13 on which the side wall 12 towards the Interior 4 springs back in the radial direction.

The interior 4 is in the adjoining the bottom part 8 Area is cylindrical and goes then into a conically narrowing section 14, which is finally closed by an end wall 15. There is a central opening in this end wall 15 16, which extends to the interior 4 stepwise. In this step-widened part 17 of the opening 16 a bearing body 18 is used, for example made of ceramic can exist and by means of an annular seal 19 opposite the housing cap 6 is sealed. To the interior 4 is this annular bearing body 18, which is concentric is arranged to the opening 16, in the form of a spherical shaped pan in which the spherical head 20 of a component referred to as nozzle body 21 is inserted.

This nozzle body 21 essentially comprises a tube 22, with constant outer and inner diameter, in the nozzle insert at the end of the bearing body 23 is used, for example also from Ceramics can exist. This nozzle insert 23 is on its outer end protruding from the tube 22 is spherical shaped and thus forms the head 20. In this nozzle insert 23 there is an outlet opening 24, the Diameter is much smaller than the inside diameter of the tube 22.

On the outside there is an annular cross section on the tube Rolling element 25 plugged on, for example Polyurethane can exist, which is set relatively soft and which is opposite the inner wall of the housing cap 6 has a high friction. This rolling element 25 is supported on an annular shoulder 26 on the outer wall of the tube 22 is thereby in one direction in axial direction.

The end of the tube 22 facing away from the bearing body 18 is immersed into the annular space 11 and holds one of the paragraph 13 small distance that is so slight that the nozzle body 21 in the housing in the axial direction only by one small path can be moved and therefore not with his head 20 emerge from storage in the bearing body 18 can.

In a stepped extension 27 at the rear, the Bearing body 18 opposite end of the tube 22 is a Plastic ring 28 used, the one from a relative soft, deformable plastic.

In the through hole 29 of the tube 22 is on this End inserted a rectifier 30, which is shown in the Embodiment two perpendicular to each other, parallel to the through hole 29 and this has diametrically penetrating walls 31. The Width of these walls 31 is over most of the length of the rectifier 30 is equal to the inside diameter of the Through hole 29, so that between two walls 31 completely separate axially parallel Channels are formed.

At the rear end of the rectifier the width of the Walls 31 too, so that the walls are in this area Dig larger width into the plastic ring 28, if the rectifier 30 in the axial direction in the through hole 29 is inserted. By digging in the rectifier 30 is fixed in the through hole 29.

The through hole 29 has the same throughout Inner diameter, so that no steps or constrictions occur, except, of course, in the area of the nozzle opening 24. The length L of the through hole 29 is at least 70mm, and the diameter d of the through hole 29 chosen so small that the ratio length L / diameter d assumes the value 17 or greater. The length l of the Rectifier 30 in the axial direction corresponds at least 0.25 the length L of the through hole 29.

The rectifier 30 has particularly thin walls, the thickness the walls 31 is namely a maximum of 1/40 of the length l of the Rectifier. To in this case the necessary strength to achieve the walls 31, there is the rectifier 30 preferably made of metal.

In operation, the cleaning liquid supplied generates a rotational flow in the interior 4, in which the Liquid inside the housing 5 about the longitudinal axis of the housing rotates. In doing so, it takes the nozzle body 21 with the rolling element 25 on the inner wall of the Housing 5 creates and rolls on it. This moves the nozzle body 21 in the interior of the housing 5 on a conical jacket, so that one from the outlet opening 24 in Direction of the through hole 29 emerging, more compact Cleaning jet circulates on a cone jacket. This compact cleaning jet is due to the specified dimensions particularly turbulence-free and compact therefore particularly suitable for cleaning purposes.

While in the embodiment of Figure 1, the nozzle insert 23 has an outlet opening, the outlet direction lies exactly on the longitudinal axis of the nozzle body 21, so that the jet from the nozzle body is exactly in the direction the longitudinal axis of the nozzle body is the Outlet direction of the outlet opening 24 in the embodiments 3 and 4 with respect to the longitudinal axis of the Nozzle body 21 inclined. This angle of inclination is in of the order of 0.5 ° to 10 °, preferably at a few degrees. This can - as in that shown in Figure 3 Embodiment - done in that a Nozzle insert 23 is used, in the outlet opening 24 is formed inclined, or by a conventional nozzle insert 23 with axially parallel outlet opening 24, wherein then the nozzle insert 23 is inclined into the nozzle body 21 is used (Figure 4).

In this way you get an orientation from the Exhaust jet emerging in complicated Way of the respective position and angular position of the Nozzle body 21 in the housing 5 depends. The nozzle body 21 is around with respect to the longitudinal axis of the housing of the rotor nozzle inclined at an angle resulting from the nozzle body 21 with a rolling element 25 on the inner wall of the interior 4 is present. The longitudinal axis of the Nozzle body on a conical surface around the longitudinal axis. The axis of the outlet opening 24 and thus the direction of the emerging beam in turn run on a cone jacket about the longitudinal axis of the nozzle body 21. The direction the axis of the outlet opening 24 with respect to the longitudinal axis the housing of the rotor nozzle thus results from a Superposition of the movements along these two conical surfaces.

A particular advantage of the construction described is that the inclination of the outlet opening is only immediate takes place in the outlet area, so that overall a very long nozzle body 21 can be used that but this does not increase the width of the nozzle body.

This is extremely important, otherwise it is a very bulky nozzle body would have to be used, which in turn a large space requirement in the housing of the rotor nozzle would result in a very large rotor nozzle. Characterized in that the inclination of the outlet opening only in the outlet area generated by the nozzle insert, a slender, yet long nozzle body are used, so that the housing of the rotor nozzle as a whole can have a small outer diameter.

Claims (12)

1. A rotor nozzle for a high-pressure cleaning appliance with a casing (5) provided in an end wall (15) with a pan-shaped, centrally perforated depression (18), with a nozzle body (21) which has a through bore (29) and which is supported by a ball-like end (20) in the pan-shaped depression (18), extends in the longitudinal direction over part of the casing (5) and has an external diameter smaller than the internal diameter of the casing (5), and with an inlet (3) - opening into the casing (5) in one direction - for a liquid, through which [inlet (3)] the liquid in the casing (5) can be set in rotation about the longitudinal axis of the casing (5) so that the nozzle body (21) circulates together with the rotating liquid and bears with an application face (25) on its periphery against the inner wall of the casing (5), wherein the longitudinal axis of the nozzle body (21) is inclined with respect to the longitudinal axis of the casing (5), and a straightener (30) with walls (31) arranged axially parallel and extending diametrically in the through bore (29) is inserted in the portion of the through bore (29) situated upstream, characterized in that the length (L) of the through bore in the nozzle body (21) amounts to at least 70 mm, the ratio of the length (L) of the through bore (29) to its diameter (d) has the value 17 or a higher figure, and the length (l) of the straightener (30) amounts to at least 0·25 of the length (L) of the through bore (29).
2. A rotor nozzle according to Claim 1, characterized in that the diameter (d) of the through bore (29) is the same throughout except for the outlet area.
3. A rotor nozzle according to Claim 1 or 2, characterized in that the thickness of the walls (31) of the straightener (30) amounts to a maximum of 1/40 of the length (l) of the straightener (30).
4. A rotor nozzle according to one of the preceding Claims, characterized in that the straightener (30) consists of metal.
5. A rotor nozzle according to one of the preceding Claims, characterized in that the width of the walls (31) of the straightener (30) corresponds over the greater part of its length (l) to the diameter (d) of the through bore (29), the walls (31) at the upstream end of the straightener (30) are slightly widened, and the widened parts of the walls (31) penetrate into an insert (28) of deformable material which forms the inner wall of the through bore (29) at the upstream end of the said through bore (29).
6. A rotor nozzle according to Claim 5, characterized in that a plastics-material ring (28), which forms the deformable material, is inserted into a widened portion (27) at the upstream end of the through bore (29).
7. A rotor nozzle according to one of the preceding Claims, characterized in that a nozzle insert (23) with an outlet opening (24), the outlet direction of which is inclined with respect to the longitudinal axis of the nozzle body (21), is arranged at the downstream end of the through bore (29).
8. A rotor nozzle according to Claim 7, characterized in that the inclination of the outlet opening (24) with respect to the longitudinal axis of the nozzle body (21) amounts to from 0·5° to 10°.
9. A rotor nozzle according to Claim 8, characterized in that the inclination of the outlet opening (24) with respect to the longitudinal axis of the nozzle body (21) amounts to from 1° to 5°.
10. A rotor nozzle according to Claim 9, characterized in that the inclination of the outlet opening (24) with respect to the longitudinal axis of the nozzle body (21) amounts to from 2° to 3·5°.
11. A rotor nozzle according to one of Claims 7 to 10, characterized in that the nozzle insert (23) is fitted axially parallel with respect to the longitudinal axis of the nozzle body (21) and has an inclined outlet opening (24).
12. A rotor nozzle according to one of Claims 7 to 10, characterized in that the nozzle body (21) receives a nozzle insert (23) with an outlet opening (24) arranged axially parallel in the nozzle insert (23), and the nozzle insert (23) is arranged in the nozzle body (21) with its own axis inclined with respect to the longitudinal axis of the nozzle body (21).

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