EP0865827A2 - Rotary nozzle for high pressure cleaning appliances - Google Patents

Abstract

The invention relates to a rotor nozzle for a high-pressure cleaning device with a housing (1) and a turbine runner (4) rotatably mounted in the housing and flowed by the cleaning liquid, with a nozzle carrier (6) arranged downstream of the turbine runner, with a nozzle, the outlet axis of which rotates with the axis of rotation of the turbine runner encloses an acute angle and which, together with the nozzle carrier, is moved by the turbine runner on a circular path about its axis of rotation such that the jet of cleaning fluid emerging from the nozzle rotates on a conical jacket, with a drive motion of the turbine runner on the nozzle carrier at a considerably reduced speed Transmitting planetary gear with a sun gear (8) connected to the turbine rotor, a planet gear (10) connected to the nozzle carrier and a ring gear (11) arranged or shaped on the inside of the housing, in which the planet gear is driven by The sun gear rolls, the nozzle being supported by a spherical front end formed on it in a pan-like seal (12) which is open in the middle and attached to the housing and is characterized in that the nozzle carrier is inclined in the direction of the outlet axis of the nozzle and that the planet gear of the planetary gear is rotatably mounted on the nozzle carrier at the rear end facing away from the spherical end. <IMAGE>

Description

The invention relates to a rotor nozzle for a high-pressure cleaning device with the Features of the preamble of claim 1.

The known rotor nozzle for a high-pressure cleaning device, of which the invention goes out (DE - U - 295 12 768) shows a planetary gear with a fixed planet carrier, which is connected to the housing. The nozzle holder with the nozzle biased axially in the direction of the seal by means of a spring element extends like a kind of sleeve around the planetary gear and forms the ring gear of the planetary gear. This has the fluidic advantages explained there. The construction is structurally complex and should be simplified.

In the known rotor nozzle explained above, it has already been mentioned that you can also connect the nozzle carrier to the planet carrier, then the ring gear would be arranged to be stationary on the inside of the housing. In this In this case, the planet gear carrier would also be gripped sleeve-like by the nozzle carrier. The cleaning fluid flowing through a flow channel in the axis of the sun gear would also be fluidically advantageous immediately in the nozzle holder enter.

Also known is a rotor nozzle which drove a high-pressure cleaning device without a gear, in which the nozzle is arranged in a stilt which is itself inclined to the axis of rotation of the Turbine rotor is aligned in the housing and with a spherical front While the end is supported in a pan that is open in the middle and held on the housing them at the opposite rear end from one connected to the turbine runner, Driven arranged at a radial distance from the axis of rotation becomes. This driver allows a free rotation about the longitudinal axis of the stilt Stilt relative to the driver. The purpose of this free rotation is that the support surface the stilt in the pan-like seal may not match the same very high speed of the turbine rotor itself rotates. This speed is below Under certain circumstances even so high that it must be limited by braking elements. For this purpose, this construction then shows centrifugal brake elements (EP - B - 0 252 261).

A rotor nozzle for a high-pressure cleaning device (DE-C-44 33 646), in which the nozzle arranged in a kind of stilt as a nozzle carrier immediately cleaning fluid, i.e. fluid mechanics, not gearbox technology is driven. Here, the nozzle holder has a radial after at the rear end projecting outside, rotatably mounted rolling ring, which is located on the inner wall of the housing passes on. This also makes sense, the self-rotation that occurs in the company of the nozzle body from the rotation of the nozzle body in contact with the Decouple the inner wall of the housing to prevent wear on the pan-like seal to reduce.

The invention is based on the object, the known rotor nozzle explained at the outset to simplify the design with planetary gears.

The task outlined above is in the rotor nozzle with the Features of the preamble of claim 1 by the features of the characterizing Part of claim 1 solved. The end of the nozzle carrier forms the bearing axis of the planet gear of the planetary gear. So you have one to the minimum reduced planetary gear, due to the bearing of the planet gear the end of the nozzle carrier, which acts as an axis in this respect, in a simple manner Decoupling of the inherent rotation of the nozzle carrier during operation from the Orbital rotation of the nozzle carrier in accordance with the reduction ratio of the Gearbox is guaranteed.

In the most common case, the planetary gear will be designed as a gear transmission. In principle, however, it is also possible to use the planetary gear as a friction gear, for example with a hard rubber roller as a planet gear on the end of the nozzle holder to execute.

Preferred refinements and developments are the subject of the dependent claims.

A further preferred teaching is the subject of independent protection claim 7, which is particularly preferably realizable in conjunction with protection claim 1 is. However, protection claim 7 may also apply to constructions of the prior art Technology that have been explained at the beginning can be realized. The execution of the Housing in aluminum has particular weight advantages, i. H. with such a High-performance rotor nozzle allows a person to work much longer than with the rotor nozzles previously on the market.

To this extent, refinements and developments are the subject of the others Subclaims.

In the following, the invention is based on an exemplary embodiment Drawing explained in more detail. In the only figure of the drawing is one preferred embodiment of a rotor nozzle for a high-pressure cleaning device in the Section shown.

A rotor nozzle of the type in question is usually at the top a cleaning lance, not shown here, of a high-pressure cleaning device. The rotor nozzle shown has a two-part housing 1, which consists of an inlet part 1a and an outlet part 1b, which is screwed together and sealed against one another are. The inlet part 1a has a water inlet 2, the outlet part 1b one Water outlet 3 on. In the housing 1, an inner cavity is formed, in which a Turbine rotor 4 is located. A flow insert is used to flow against the turbine rotor 4 5, which corresponds to the water entering at the water inlet 2 Channels on the turbine rotor 4 directs.

A nozzle carrier 6 with a nozzle 7 is arranged downstream of the turbine rotor 4, whose exit axis forms an acute angle with the axis of rotation of the turbine rotor 4 includes. The nozzle carrier 6 with the nozzle 7 is opened by the turbine runner 4 a circular path around its axis of rotation (translation on a circular path) that the jet of cleaning liquid emerging from the nozzle 7 on a cone jacket circulates. The nozzle holder 6 is elongated, stilt-like and the Nozzle 7 is inserted as a separate part in the nozzle holder 6. There are reasons for that Choice of materials. In principle, it would also be possible that the nozzle 7 in the nozzle carrier 6 is integrally formed.

The drive movement of the turbine rotor 4 is reduced considerably Transfer speed to the nozzle carrier 6, namely through a planetary gear. This consists of a connected to the turbine rotor 4 sun 8, which in illustrated embodiment in the middle of a flow channel 9 for the under high Has pressure flowing water. Also shown is a planet gear 10 meshes with the sun gear 8, and a ring gear 11 in which the planet gear 10 rolls.

With a spherical front end formed on it, the nozzle 7 is supported in a open in the middle, attached to the housing 1 pan-like seal 12. The seal 12 itself is made of highly wear-resistant material and itself inserted again in an insert 13 at the water outlet 3.

The ring gear 11 of the planetary gear is arranged on the inside of the housing 1, in the illustrated embodiment on a gear insert 14 which between Inlet part 1a and outlet part 1b of the housing 1 is inserted and jammed. The Ring gear 11 can also be formed on the inside of the housing 1. The nozzle holder 6 is arranged inclined in the direction of the outlet axis of the nozzle 7. On the Nozzle carrier 6 is the planet gear at the rear end facing away from the spherical end 10 of the planetary gear rotatably mounted. One recognizes the indicated intermeshing rows of teeth of the various wheels of the planetary gear.

A rapid rotation of the turbine rotor 4 causes the reduction ratio the planetary gear, for example a reduction ratio of 6: 1, correspondingly reduced a slow rotation of the planet gear 10 with the connected to the turbine runner 4, at the speed of which the sun gear 8 rotates. This causes the water jet ejected from the nozzle 7 in the nozzle carrier 6 to circulate on a cone jacket.

The structure of the rotor nozzle shown is despite the use of a reduction gear in the form of a planetary gear extremely easy.

For technical reasons, it could be provided that the nozzle carrier 6 supported planet gear 10 with at least one further planet gear, preferably two further planet gears that run freely, preferably in a planet carrier, is combined. The side pressure on the sun gear 8 through the planet gear 10 would be compensated for what is technically appropriate in terms of transmission technology.

The illustrated embodiment shows the planetary gear as a gear transmission. In a similar way, it could also be designed as a friction gear, for example with the planet gear 10 designed as a hard rubber roller on the end of the nozzle holder 6 is rotatably mounted.

As in the prior art from which the present invention is based, the Nozzle 7 in the nozzle carrier 6 cannot be rotated about its own longitudinal axis, but in the axial direction be slidably disposed relative to the nozzle carrier 6. The rotatability the nozzle 7 in the nozzle carrier 6 is because of the possible rotation of the nozzle carrier 6 compared to the planet gear 10 is not necessary. The axial displaceability the nozzle 7 in the nozzle carrier 6 has the advantages already explained in the prior art in terms of operation and manufacturing tolerance. Also a preload using a spring element in a manner known from the prior art could be provided be.

Not shown or not necessarily recognizable in the drawing is that it is advantageous can be that a flow insert 5 is provided, which at the water inlet 2nd incoming water directs corresponding channels on the turbine runner 4, and that the number and arrangement of the water passages in the flow insert 5 different are selectable, if necessary by choosing different flow inserts 5 so as to determine the rotational speed and rotational speed of the turbine rotor 4.

It is particularly preferred that the housing 1 made of aluminum, in particular of a Aluminum alloy. In the illustrated embodiment, it is provided that the nozzle carrier 6 is in contact with the inner surface of the housing when rotating 1 does not have. It is further provided in the illustrated embodiment that the ring gear 11 of the drive movement of the turbine rotor 4 on the nozzle carrier 6 transmitting planetary gear as a separate, wear-resistant part on the housing 1 is arranged. The corresponding insert part, namely the gear insert, can be seen here 14. This can be made of highly wear-resistant material, in particular a corresponding metal, while the rest of the case, at least the housing part 1b, made of aluminum.

Even in the case of a rotor nozzle with a bearing on the inner wall of the housing 1 revolving nozzle carrier 6, in particular without an intermediate gear, you could realize a housing 1 made of aluminum, if you touch the track equips the nozzle holder 6 with appropriate wear resistance, ie accordingly coated or provided with an insert or an insert.

Claims (10)

Rotor nozzle for a high pressure cleaning device
with a housing (1) and a turbine rotor (4) which is rotatably mounted in the housing (1) and flows against by the cleaning liquid,
with a nozzle carrier (6) arranged downstream of the turbine rotor (4) with a nozzle (7), the outlet axis of which forms an acute angle with the axis of rotation of the turbine rotor (4) and which together with the nozzle carrier (6) from the turbine rotor (4) are thus on one Circular path is moved about its axis of rotation so that the jet of cleaning liquid emerging from the nozzle (7) revolves on a cone jacket,
with a planetary gear that transmits the drive movement of the turbine rotor at a considerably reduced speed to the nozzle carrier (6) with a sun gear (8) connected to the turbine rotor (4), a planet gear (10) connected to the nozzle carrier (6) and one on the inside of the Housing (1) arranged or molded ring gear (11), in which the planet gear (10) rolls driven by the sun gear (8),
the nozzle (7) being supported by a spherical front end formed on it in a pan-like seal (12) which is open in the middle and fastened to the housing (1),
characterized, that the nozzle carrier (6) is arranged inclined in the direction of the outlet axis of the nozzle (7) and that the planet gear (10) of the planetary gear is rotatably mounted on the nozzle carrier (6) at the rear end facing away from the spherical end. Rotor nozzle according to claim 1, characterized in that the nozzle (7) in the nozzle carrier (6) is used or is integrally formed in the nozzle carrier (6). Rotor nozzle according to claim 1 or 2, characterized in that the nozzle carrier (6) rotatably mounted planet gear (10) with at least one further planet gear, preferably two further planet gears that run freely, preferably in a planet carrier is combined. Rotor nozzle according to one of claims 1 to 3, characterized in that the Planetary gear is designed as a gear transmission. Rotor nozzle according to one of claims 1 to 3, characterized in that the Planetary gear is designed as a friction gear. Rotor nozzle according to one of claims 1 to 5, characterized in that a Flow insert (5) is provided, the water entering the water inlet (2) directs via appropriate channels on the turbine rotor (4), and that number and Arrangement of the water passages in the flow insert (5) can be selected differently are, optionally by choosing different flow inserts (5), so the To determine the speed and speed of rotation of the turbine rotor (4). Rotor nozzle for a high-pressure cleaning device with a housing (1) and a nozzle holder (6) rotatably mounted in the housing (1) with a nozzle (7) which is moved together with the nozzle holder (6) so that the nozzle nozzle (7) exits Jet of cleaning liquid circulates on a cone jacket, in particular according to one of claims 1 to 6,
characterized, that the housing (1) made of aluminum, in particular an aluminum alloy. Rotor nozzle according to claim 7, characterized in that the nozzle carrier (6) has no contact with the inner surface of the housing (1) when rotating. Rotor nozzle according to claim 7, characterized in that the nozzle carrier (6) when rotating the inner surface of the housing (1) touches the material of the housing (1) in the contact area, however, wear-resistant, in particular coated or is provided with an insert. Rotor nozzle according to one of claims 7 to 9, characterized in that a Ring gear (11) of the drive movement of a turbine rotor (4) on the nozzle carrier (6) transmitting planetary gear as a separate, wear-resistant part on the housing (1) is arranged.

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