EP0372182A2 - Rotor nozzle for a high-pressure cleaning device - Google Patents

Abstract

In the case of a rotor nozzle for a high-pressure cleaning device with a housing, a rotor (10) rotatably mounted therein and caused to rotate by a cleaning liquid, and with a nozzle (33) arranged downstream of the rotor (10), the outlet axis of which rotates with the axis of rotation of the rotor (10). Includes a variable acute angle and which is rotated by the rotor (10) about its axis of rotation in such a way that the emerging jet of the cleaning liquid rotates on a conical jacket, to allow the exit angle of the spot jet to be adjusted without having to change other parameters, that adjustable stops (46) are arranged in the housing (1), which more or less limit a widening of the acute angle between the outlet axis of the nozzle (33) and the axis of rotation of the rotor (10), depending on the position of the limiting elements.

Description

The invention relates to a rotor nozzle for a high-pressure cleaning device with a housing, a rotor rotatably mounted therein and rotated by the cleaning fluid and with a nozzle arranged downstream of the rotor, the outlet axis of which includes a variable acute angle to the axis of rotation of the rotor and which is rotated by the rotor in such a way whose axis of rotation is rotated so that the emerging jet of cleaning liquid rotates on a cone jacket.

Such a rotor nozzle is known from German Patent 36 23 368. It enables a point jet to be emitted which revolves on a cone shell, the angle of the cone shell being able to be widened as a function of the speed in the known rotor nozzle.

It is an object of the invention to develop a generic rotor nozzle so that the operator can adjust the angle of the cone shell, on which the spot beam rotates, in a targeted manner, independently of other operating parameters.

This object is achieved in a rotor nozzle of the type described in the introduction in that adjustable stops are arranged in the housing, which limit a widening of the acute angle between the outlet axis of the nozzle and the axis of rotation of the rotor depending on the position of the limiting elements.

By adjusting the stops, it is possible to limit an inclined position of the nozzle and thus an increase in the opening angle of the cone shell, the operator being able to move these stops in the housing of the rotor nozzle, so that the stops then have a differently wide inclination of the nozzle outlet axis compared to the rotor axis of rotation.

In the case of a rotor nozzle with a stilt which receives the nozzle and is supported with a spherical end in a pan which is open in the middle and held on the housing, while at the other end a driver connected to the rotor and arranged at a radial distance from the rotor axis engages it is particularly advantageous if the stop surrounds the stilt concentrically to the axis of rotation of the rotor, is adjustable in the direction of the axis of rotation of the rotor and forms a circumferential contact edge lying on the outside of the stilt.

It can be provided that the stop in the housing is axially displaceable and rotatably mounted with respect to the axis of rotation of the rotor and is screwed into a threaded bore of an adjusting sleeve arranged coaxially to the axis of rotation of the rotor, which is axially immovable in the housing and freely rotatable with respect to the axis of rotation of the rotor is. Simply by turning this adjustment sleeve, the stop inside the housing can then be moved in the axial direction, so that the exit angle of the spot beam is infinitely adjustable.

It is also advantageous if the driver carries a radial groove in which the stilt is immersed with a driving pin.

The adjustment sleeve can close the front of the housing and support the pan for storing the stilts. In this way, the adjusting sleeve practically forms part of the housing, the two housing parts being rotated relative to one another about the longitudinal axis of the housing in order to achieve a change in the beam opening angle.

In a particularly preferred embodiment it is provided that a closable bypass line also exits from the interior of the housing located upstream of the nozzle into the region of the rotor nozzle located immediately downstream of the nozzle. As a result, part of the cleaning liquid is guided past the nozzle, so that the pressure of the point jet emerging from the nozzle can be varied. This pressure variation is also supported by the fact that the amount of liquid carried past the nozzle in the bypass re-enters the point jet in the region downstream of the nozzle, thereby tearing it open and fanning it out. Overall, this results in a less sharply focused point beam with a lower exit speed and therefore with a lower impact speed.

It can be provided that the bypass line comprises a plurality of bypass channels surrounding the nozzle, which are preferably all constructed identically.

The effect of the liquid bypassing the nozzle is particularly advantageous if the bypass line emerges from its wall in a funnel which immediately adjoins the nozzle and widens conically in the direction of flow, in particular if the bypass line essentially extends in a direction perpendicular to the axis of rotation of the rotor arranged radial plane enters the funnel, ie essentially perpendicular to the beam direction. Through the funnel-shaped walls, the amount of liquid emerging through the bypass line is deflected in the direction of the point jet and entrained by it, so that there is a coating of the sharp core of the point jet which, until it hits an area to be cleaned, is fanned out to form an essentially homogeneous one Beam leads.

It is advantageous if metering valves are arranged in the bypass line, the position of which can be adjusted by adjusting members arranged on the outside of the rotor nozzle. These allow a continuous or a gradual metering of the amount of liquid flowing through the bypass line, so that the operator has the possibility of adjusting the jet between a sharply focused, pure point jet and a highly diversified, largely homogeneous jet.

A particularly favorable solution for the adjustment of the metering valves is obtained if an adjusting ring is rotatably mounted on the housing concentrically to the axis of rotation of the rotor and has on its inside bearing surfaces for valve bodies of the metering valves protruding radially from the housing and elastically pressed against the bearing surface. and if the contact surfaces on rotation of the adjusting ring in the contact area against the valve body are at a different radial distance from the axis of rotation of the adjusting ring exhibit. Simply by turning the adjusting ring, the bypass line can thus be opened and closed in a metered manner, so that the operator can control the nature of the jet essentially continuously between a point jet and an expanded jet with a circular cross section without additional tools.

In a further preferred exemplary embodiment, a closable bypass branching upstream of the rotor from the flow path of the cleaning liquid can also be provided, which bypasses the rotor in such a way that the cleaning liquid flowing through it does not contribute to the rotary drive of the rotor. This results in the possibility of determining the rotation of the rotor and in particular the speed of rotation of the rotor only by part of the liquid, while another part is guided past the rotor. This can affect the speed. It is particularly advantageous if the bypass can be closed in a metered manner, since in this way the speed can be varied in accordance with the closed state of the bypass.

In a preferred embodiment, in which the rotor is rotatably mounted on a hollow shaft which supplies the cleaning liquid to the inside of the rotor, it can be provided that a piece of pipe axially displaceably mounted in the housing is immersed in the hollow shaft, which in the fully inserted state relative to the hollow shaft is essentially sealed, but when pulling out of the hollow shaft forms a connection between the interior of the pipe section and the bypass. Such a structurally very simple and robust arrangement enables the metered diversion of part of the cleaning liquid and thus also the metered speed control of the rotor.

It has proven to be advantageous if the pipe section has lateral wall openings which are covered by the hollow shaft when the pipe section is fully inserted, but are released from the wall of the hollow shaft when the pipe section is pulled out of the hollow shaft, and if an annular channel surrounding the pipe section is one Forms part of the bypass. The adjustment of the pipe section is particularly simplified if the pipe section is screwed into an internally threaded bore of the housing that runs coaxially to the axis of rotation of the rotor. The ratio of the amount of liquid passed through the rotor to the amount of liquid passed by the rotor and thus the speed of rotation of the rotor which is set can be continuously adjusted simply by rotating the pipe section relative to the housing and by the associated axial displacement in the thread.

• Figur 1: eine Längsschnittansicht einer Rotor­düse mit Drehzahlverstellung des Rotors, Winkelverstellung der Düse und Druck­verstellung des Strahles bei einer Ein­stellung für maximale Drehzahl, maxima­len Öffnungswinkel des Punktstrahles und geöffneter Bypass-Leitung zur Auf­fächerung des Punktstrahls und
• Figur 2: eine Seitenansicht eines weiteren be­vorzugten Ausführungsbeispieles einer teilweise aufgebrochen dargestellten Rotordüse mit einer Einstellung für minimale Drehzahl, minimalen Öffnungs­winkel des Strahles und mit verschlossener Bypass-Leitung zur Erzeugung eines nicht aufgefächerten Punktstrahles.

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

• Figure 1: a longitudinal sectional view of a rotor nozzle with speed adjustment of the rotor, angle adjustment of the nozzle and pressure adjustment of the jet at a setting for maximum speed, maximum opening angle of the spot jet and open bypass line for fanning out the spot jet and
• Figure 2 is a side view of another preferred embodiment of a partially broken open Rotor nozzle with a setting for minimum speed, minimum opening angle of the jet and with a closed bypass line to generate a non-fanned spot jet.

The rotor nozzle shown in Figure 1 comprises a cylindrical housing 1 which carries an internally threaded bore 2 on one side, while it is open on the opposite side. The inner threaded bore 2 is followed by a bore with a smooth inner wall 4, which merges into a bearing bore 5 with a reduced inner diameter and finally opens into the cylindrical interior 6 of the housing 1, the inner diameter of which is substantially larger than the inner diameter of the bearing bore 5.

A hollow shaft 7 is inserted into the bearing bore 5, which is supported with an annular flange 8 on the step 9 between the inner wall 4 of the bore 2 and the bearing bore 5 and which projects into the interior 6 of the housing. On the part of the hollow shaft 7 protruding into the interior 6, a rotor 10 is rotatably mounted, which has two arms 12 projecting radially from the hollow shaft 7 and reaching as far as the inner wall 11 of the interior 6. The rotor 10 is secured on the hollow shaft 7 in the axial direction on the one hand by a step 13 on the outer circumference of the hollow shaft 7 and on the other hand by a screw 14 which is screwed into the free end of the hollow shaft 7 and thereby closes the end of the hollow shaft 7.

The hollow shaft 7 has at the height of the arms 12 of the rotor 10 wall openings 16 which connect the interior of the hollow shaft 7 with the interior 17 of the rotor 10, which again through holes 18 in the arms 12 with outlet openings 19 to the Ends of the arms 12 communicates. The outlet openings point in opposite directions in the circumferential direction, so that liquid escaping through the outlet openings 19 rotates the rotor on the hollow shaft 7.

The liquid supply to the hollow shaft 7 takes place via a pipe piece 20 screwed into the internally threaded bore 2, which carries a coupling ring on the part emerging from the housing 1 for connection to a jet pipe of a high-pressure cleaning device (not shown in the drawing), while on the opposite side into the Hollow shaft 7 immersed. The pipe section 20 is sealed by means of an annular seal 22 with respect to the smooth inner wall 4 of the bore 2, in addition the tubular section 20 also carries a further annular seal 23 in a conically narrowing transition region 24, which seals a complementary one when the tubular section 20 is fully inserted into the hollow shaft 7 Sealing surface 25 lies in the entry area into the hollow shaft 7. In the immediate vicinity of the free end of the pipe section 20, a plurality of radial openings 26 are arranged in the wall of the pipe section, which are sealed off from the inner wall of the hollow shaft 7 when the pipe section 20 is fully inserted into the hollow shaft 7, as shown in FIG. 1.

The pipe section 20 can be rotated in the internal threaded bore 2 with respect to the housing 1 and thereby displaced in the axial direction until the interior of the pipe section 20 is connected via the openings 26 to the annular channel 27 formed by the bore 2 and surrounding the pipe section 20, such as this is shown in the embodiment of Figure 2. This ring channel 27 is connected via a series of channels 28 directly to the interior 6 of the housing 1, so that part of the liquid supplied through the pipe section 20 is bypassed on the rotor 10 is led past. This bypass is formed by the openings 26 in the pipe section 20, by the ring channel 27, by the channels 28 and by the interior 6 of the housing. In the interior 6 of the housing, the liquid which bypasses the rotor is combined again with the liquid which has flowed through the interior of the rotor and reaches the interior 6 through the outlet openings 19.

By screwing the pipe section 20 more or less deeply into the housing 1, the division of the two partial flows can be varied until all the liquid is passed through the rotor 1 when the pipe section 20 is fully inserted (FIG. 1). This allows the rotor speed to be continuously adjusted.

On the rotor 10, the end of the hollow shaft 7 and the screw 14, which closes the latter, cap-shaped and rotatably mounted, a driver 29 which has a groove or opening 30 running radially from the center to the outside. A driver pin 31 of a stilt 32, which carries a nozzle 33 with a spherical head, plunges into this groove. This stilt 32 has lateral openings 34, which connect the interior 6 of the housing 1 to the nozzle opening 36 in the nozzle 33 via a central channel 35 in the stilt 32.

This stilt is supported with the spherical part of the nozzle 33 in a central bearing socket 37 which has a central opening 38 in alignment with the nozzle opening 36. The bearing socket 37 is arranged in the end wall 39 of an adjusting sleeve 40, which plunges into the open end of the housing 1 in a sealed manner by means of an annular seal 41 and is mounted on the housing 1 so that it cannot move and can rotate freely in the axial direction. For this purpose points the housing has an annular groove 42 on its inner wall and the adjusting sleeve 40 has an annular groove 43 aligned with the annular groove 42 on its outer wall, into which a clip 44 is inserted.

On the inside, the adjusting sleeve 40 has an internal thread 45, into which a hood-shaped stop 46 is screwed, which engages in longitudinal grooves 48 on the inner wall of the interior 6 of the housing 1 by means of laterally projecting guide projections 47 and thereby the hood-shaped stop 46 relative to the housing 1 axially displaceable, but non-rotatably.

When the adjusting sleeve 40 is rotated relative to the housing 1, the hood-shaped stop 46 thus screws more or less deeply into the internal thread 45, that is to say the stop 46 can also be shifted between a fully screwed-in position (FIG. 1) into a position in which the rotor 10 is approximated. In this position, the hood-shaped stop 46 extends over the driver 29 of the rotor 10 (FIG. 2).

At its end facing the end wall 39 of the adjusting sleeve 40, the stop 46 is provided with an inwardly projecting stop edge 49 which runs concentrically to the axis of rotation of the rotor and which abuts the outer wall of the stilt 32 and thus the inclination of the stilt 32 relative to the axis of rotation of the rotor limited. In the position of the stop 46 shown in FIG. 1, in which it is completely screwed into the internal thread 45, a very extensive inclination is possible, whereas in the extreme case of the stop completely screwed out, an inclination of the stilt 32 is prevented at all, so the exit axis of the nozzle practically coincides with the axis of rotation of the rotor.

By rotating the adjusting sleeve 40 relative to the housing 1, it is thus possible to adjust the stop 46 in the axial direction and thus the maximum opening angle between the outlet axis of the nozzle and the axis of rotation of the rotor.

The hood-shaped stop 46 also forms a collecting space 50 for the liquid entering the interior 6. This collecting space 50 is conically narrowed in the part facing the nozzle 33, so that the liquid is supplied on the one hand to the openings 34 in the stilt 32, but on the other hand to the central opening 51 which is surrounded by the stop edge 49 and through which the stilt 32 passes through.

In the end wall 39 of the adjusting sleeve 40, the bearing socket 37 is provided concentrically surrounding a plurality of bores 52 which are parallel to the axis of rotation of the rotor and which open into radial bores 53 of the adjusting sleeve 40 leading from the outside inwards. These radial bores 53 initially have an enlarged outer part 54 and then an inner part 55 with a reduced cross section, which opens into a central, funnel-shaped opening 56 in the adjusting sleeve 40, which adjoins the opening 38 of the bearing socket 37 connects. The bores 53 enter the funnel-shaped opening 56 in the radial direction.

In the outer part 54 of the bores 53, valve bodies 57 which are displaceable in the longitudinal direction of the bore are arranged, which are sealed off from the bore 53 by means of ring seals 58 and optionally close or release the bore 53 in the transition region between the outer part 54 and the inner part 55. In the execution case 1 of FIG. 1, the valve bodies 57 are pressed radially outward by a coil spring 59 arranged in the outer part 54 of the bore 53 against a contact surface 60 on an adjusting ring 61, which in turn is rotatably mounted on an external thread 62 of the adjusting sleeve 40. The contact surface 60 has different distances in the axial direction from the axis of rotation of the adjusting ring 61, so that when the adjusting ring 61 is rotated, the valve body 57 is pressed into the bore 53 to a different depth against the action of the helical spring 59, and the flow cross section of the bore 53 is more or less release less or close completely when fully inserted. This gives a metering valve which can be actuated continuously by rotating the adjusting ring 61 in each bore 53. By means of these metering valves, a partial flow can be passed directly past the nozzle 33 into the funnel-shaped opening 56, which mixes there with the point jet emerging from the nozzle opening 36. On the one hand, this reduces the exit velocity in the point jet, since the amount of liquid becomes smaller, on the other hand, the amount of liquid entering the point jet at the side tears open and mixes with the amount of liquid in the point jet to form a fanned out, voluminous jet with a circular cross-section and a lower impact velocity of the liquid particles . This transition can be varied continuously by adjusting the metering valves.

In the exemplary embodiment in FIG. 1, the bypass line formed by the bores 52 and 53 is opened; in the exemplary embodiment in FIG. 2, however, the metering valves are shown closed. In the embodiment of FIG. 2, in addition to that of FIG. 1, the adjustment of the valve body is not over one made of the adjusting sleeve rotatable adjusting ring, but the valve bodies 57 are screwed into the outer part 54 of the bore 53 and can be rotated directly via knurled disks 63 and adjusted to different immersion depths.

Overall, a rotor nozzle is obtained which initially gives the possibility of steplessly adjusting the angle of the point jet emerging from the nozzle between 0 and a maximum value, for example 10 °. It is also possible to continuously adjust the speed of the jet by not directing part of the liquid through the rotor, but past the rotor. Finally, the nature of the jet itself can also be changed by dividing the liquid flow through the nozzle 33 and adding a quantity of liquid transversely to the point jet. Overall, you get a very variable rotor nozzle, which is robust in construction and allows easy operation of the various adjustment options. In the embodiment of Figure 1, all three variations can be made by rotating individual parts around the longitudinal axis of the housing, namely by rotating the entire housing relative to the pipe socket fixed to the jet pipe, by rotating the adjusting sleeve relative to the housing and finally by rotating the adjusting ring relative to the adjusting sleeve , the outside of the housing, adjusting sleeve and adjusting ring being in alignment and thus a cylindrical outer contour for the entire rotor nozzle can be maintained.

Claims (16)

1.Rotor nozzle for a high-pressure cleaning device with a housing, a rotor which is rotatably mounted therein and rotated by the cleaning liquid and with a nozzle arranged downstream of the rotor, the outlet axis of which includes a variable acute angle to the axis of rotation of the rotor and that of the rotor about its axis of rotation rotated so that the emerging jet of cleaning liquid circulates on a conical jacket,
characterized in that adjustable stops (46) are arranged in the housing (1), which more or less limit a widening of the acute angle between the exit axis of the nozzle (33) and the axis of rotation of the rotor (10) depending on the position of the stops (46). 2. Rotor nozzle according to claim 1 with a nozzle (33) receiving stilt (32), which is supported with a spherical end in an open in the middle, on the housing (1) held pan (37), while at the other end with driver (29) connected to the rotor (10) and arranged at a radial distance from the rotor axis, characterized in that the stop (46) surrounds the stilt (32) concentrically to the axis of rotation of the rotor (10), is adjustable in the direction of the axis of rotation of the rotor (10), and a circumferential contact edge (12) resting on the outside of the stilt (32) 49) forms. 3. Rotor nozzle according to claim 2, characterized in that the stop (46) in the housing (1) is axially displaceable and rotatably mounted with respect to the axis of rotation of the rotor (10) and in a coaxial to the axis of rotation of the rotor (10) arranged threaded bore (45 ) an adjusting sleeve (40) is screwed in, which is axially immovable on the housing (1) and is freely rotatable with respect to the axis of rotation of the rotor (10). 4. Rotor nozzle according to one of claims 2 or 3, characterized in that the driver (29) carries a radial groove (30) into which the stilt (32) with a driver pin (31) is immersed. 5. Rotor nozzle according to one of claims 3 or 4, characterized in that the adjusting sleeve (40) closes the end face of the housing (1) and carries the pan (37) for mounting the stilts (32). 6. Rotor nozzle according to one of the preceding claims, characterized in that a closable bypass line (52, 53) from the upstream of the nozzle (33) located interior (6) of the housing (1) in the immediately downstream of the nozzle (33) Area of rotor nozzle emerges. 7. rotor nozzle according to claim 6, characterized in that the bypass line (52, 53) comprises a plurality of the nozzle (33) surrounding bypass channels. 8. Rotor nozzle according to claim 6 or 7, characterized in that the bypass line (52, 53) in a directly after the nozzle (33) adjoining, widening conically in the flow direction funnel (56) emerges from the wall. 9. A rotor nozzle according to claim 8, characterized in that the bypass line (52, 53) substantially in a radial plane arranged perpendicular to the axis of rotation of the rotor (10) enters the funnel (56). 10. Rotor nozzle according to one of claims 6 to 9, characterized in that in the bypass line (52, 53) metering valves (57) are arranged, which are adjustable in position by means of adjusting members (61; 63) arranged on the outside of the rotor nozzle . 11. Rotor nozzle according to claim 10, characterized in that on the housing (1) concentrically to the axis of rotation of the rotor (10), an adjusting ring (61) is rotatably mounted, on its inside bearing surfaces (60) for radially from the housing (1 ) protruding, elastically pressed onto the contact surface (60) of the valve body (57) Dosing valves and that the contact surfaces (60) have a different radial distance from the axis of rotation of the adjusting ring (61) when the adjusting ring (61) is rotated in the contact area on the valve bodies (57). 12. Rotor nozzle according to one of the preceding claims, characterized in that an upstream of the rotor (10) from the flow path of the cleaning liquid branching, closable bypass (26, 27, 28) is provided, which leads past the rotor (10) such that the cleaning fluid flowing through it does not contribute to the rotary drive of the rotor (10). 13. Rotor nozzle according to claim 12, characterized in that the bypass (26, 27, 28) can be closed in a metered manner. 14. A rotor nozzle according to claim 12 or 13, wherein the rotor (10) is rotatably mounted on a hollow shaft (7) which supplies the cleaning liquid to the inside of the rotor (10), characterized in that in the hollow shaft (7) in the housing (1) immerses axially displaceably mounted pipe section (20) which, when fully inserted, is essentially sealed off from the hollow shaft (7), but when pulled out of the hollow shaft (7) it connects the interior of the pipe section (20) with the bypass ( 26, 27, 28). 15. Rotor nozzle according to claim 14, characterized in that the tube piece (20) lateral wall openings (26) which are covered by the hollow shaft (7) when the pipe section (20) is fully inserted, but are released from the wall of the hollow shaft (7) when the pipe section (20) is pulled out of the hollow shaft (7), and that the pipe section ( 20) surrounding ring channel (27) forms part of the bypass (26, 27, 28). 16. Pipe section according to one of claims 14 or 15, characterized in that the pipe section (20) is screwed into an internally threaded bore (2) of the housing (1) which extends coaxially to the axis of rotation of the rotor (10).

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