CH717511A2 - Rotor body of a pipe cleaning nozzle, with molded attachment means. - Google Patents

Abstract

In a pipe cleaning nozzle rotor body (10) according to the invention, comprising a feed channel (101) and a branch channel branching off from it with several outlet channels, the possibility of easier attachment of the rotor body to a stator body should be created. This is achieved in that the rotor body (10) is made of metal using an additive manufacturing process or 3D printing and fastening means (1010) are formed directly on the rotor body (10) or are recessed.

Description

technical field

The present invention describes a rotor body of a pipe cleaning nozzle, comprising a feed duct and a branch duct branching off from it with a plurality of outlet ducts, a cleaning nozzle with a rotor body, a manufacturing method for manufacturing a rotor body of a pipe cleaning nozzle and a lance of a lance device for cleaning pipe bundles.

State of the art

There are so-called cross-jet cleaning nozzles for cleaning pipes and manholes, known as a subspecies of high-pressure pipe cleaning nozzles. Such cross-jet cleaning nozzles have a rotor body with a plurality of channels and nozzles, which is rotatably mounted on a stator body 20 in the assembled state. FIG. 1 shows a rotor body 10 according to the prior art in a schematic longitudinal section. Two cross-jet cleaning nozzle channels are recessed in the rotor body 10 in such a way that exiting cleaning fluid jets, indicated by dashed lines, intersect during operation.

In practice, the rotor body 10 or the cross-jet cleaning nozzle 1 is preferably placed on a lance of a lance device that can be operated in a controlled manner for the automatic cleaning of tube bundles. Those skilled in the art are familiar with lances and lance devices, which are therefore not further explained or shown here for the sake of simplicity. The rotor body 10 is rotatably mounted about a longitudinal axis L on the stator body 20 or a stator body tip 205, with the nozzles having different functions.

The well-known cross-jet cleaning nozzles 1 and their rotor body 10 and stator body 20, like other pipe cleaning nozzles, are made of metal, are milled from the solid and have drilled channels, drilled in different directions. As can be seen in FIG. 1, the channels are introduced into the rotor body 10 in a straight line from several sides or in different directions. This type of production has proven itself and has led to inexpensive, suitable cross-jet cleaning nozzles 1 with good cleaning results. In order to keep the stator body tip 205 and thus the stator body 20 rotatable relative to the rotor body 10 within the feed channel 101, at least one screw or plug connection of connecting means, in particular of securing pins, has been used to date, approximately perpendicular to the longitudinal axis L through correspondingly attached channels in the rotor body 10. The safety pins, which engage in an annular groove on the tip 205 of the stator body, are indicated by dashed lines in FIG. In addition to cutting out the necessary channels for the locking pins, a further manufacturing step is always necessary, with the stator body tip 205 being fastened by means of the at least one additional locking pin. A complicated and complex attachment can thus be created in order to enable the rotational movement of the rotor body 10 .

Presentation of the invention

The present invention has set itself the task of creating a rotor body of a pipe cleaning nozzle, which ensures easier attachment of the rotor body to the stator body.

This problem is solved by a rotor body of a pipe cleaning nozzle, in particular a cross-jet cleaning nozzle with the features of claim 1, with the manufacturing method in particular leading to the solution of the problem.

Due to the additive manufacturing process, subsequent attachment of the rotor body to the stator body with external or removable fasteners is no longer necessary. The manufacturing method of the rotor body is also claimed accordingly.

Variations of combinations of features or minor adjustments of the invention can be found in the detailed description, shown in the figures and included in the dependent claims.

Since the inventive rotor body of cross jet cleaning nozzles can be used in suitable lances of lance devices and is advantageously used in practice, a suitably equipped lance of the lance device with at least one cross jet cleaning nozzle or a suitable rotor body is also claimed.

Brief description of the drawings

The subject of the invention is described in detail below in connection with the accompanying drawings. Necessary features, details and advantages of the invention emerge from this following description, in which a preferred embodiment of the invention and some additional features or optional features are listed in detail.

There are shown in Figure 1 shows a schematic sectional drawing of a rotor body of a cross-jet cleaning nozzle, known from the prior art. Figure 2 shows a schematic partial sectional view along the longitudinal axis of a cross-jet cleaning nozzle with a rotor body according to the invention, while Figure 3a shows a front view of the cross-jet cleaning nozzle or the rotor body, Figure 3b shows a schematic longitudinal section through the rotor body and the stator body tip along a first section line and Figure 3c shows a second schematic longitudinal section through the rotor body and the stator body tip along a second line of intersection.

description

A pipe cleaning nozzle 1 is shown and described using the example of a cross jet cleaning nozzle 1, which comprises a rotor body 10 with a plurality of channels or nozzles. Here, the cross-jet cleaning nozzle 1 is designed in two parts, with the rotor body 10 being rotatably mounted on a stator body 20 . For the sake of simplicity, no lance and no lance device is shown here, but the cross-jet cleaning nozzle 1 alone. The rotor body 10 is mounted such that it can rotate about a longitudinal axis L, is detachably connected to the stator body 20 and the possibility of rotation is indicated by a double arrow in FIG. 2, with the nozzles having different functions.

In the rotor body 10, a feed channel 101, a branch channel 102 and here two cross-jet nozzle channels 103 are recessed.

After the production of the rotor body 10 or the stator body 20, nozzle inserts are usually introduced into the outlets of the channels and the cross-jet cleaning nozzle 1 is pressurized by means of a high-pressure connection with pressure medium, usually water, with pressures of up to 3000 bar. Even when the rotor body 10 is rotating at several hundred revolutions per minute, the cross-jet cleaning nozzle 1 can be guided easily and safely through pipes in the feed direction V.

On the non-rotatable stator body 20, a feed section 200 is arranged, to which a hose with cleaning fluid can be coupled under high pressure. The feed section 200 opens into a stator feed channel 201 which preferably runs concentrically to the longitudinal axis L of the stator body 20 and is recessed. On the stator body side, the stator supply channel 201 opens into at least one thruster nozzle channel 202. Three thruster nozzle channels 202 are provided here, the outlets of which are provided with nozzle inserts (not shown). These thruster nozzle channels 202 provide a thrust for movement in the feed direction V. The stator feed channel 201 runs further into a rotor body bearing 203 on which the rotor body 10 is rotatably mounted and which is inserted into the feed channel 101 in the rotor body 10 . In the course of the stator feed channel 201, this opens into a central outlet 204. This allows cleaning fluid to escape from the stator body 20 or the stator feed channel 201 into the feed channel 101 or the branch channel 102 in the rotor body 10.

The stator body 20 and rotor body 10 are detachably connected to one another. With the nozzle tip D in front, the cross-jet cleaning nozzle 1 is guided through pipes whose inner diameter can only be slightly larger than the outer diameter of the rotor body 10 . An optimal cleaning effect can be achieved by the cross jets from the two cross jet nozzle channels 103 .

As can be seen in the front view of the cross jet cleaning nozzle 1 according to FIG. 3a, at least one front jet channel 104 can be arranged so that it emerges centrally from the nozzle tip D. The front jet channel 104 must be connected to the feed channel 101 inside the rotor body 10 accordingly. The same applies to at least one radial nozzle channel 105 indicated by dashed lines, which exits radially from the rotor body 10 slightly offset relative to the longitudinal axis L. If cleaning fluid exits the front jet channel 104, an additional cleaning effect results in the feed direction V, while liquid exiting through the at least one radial nozzle channel 105 leads to the rotation of the rotor body 10. If one looks at the nozzle tip D from the side, the crossing of the fluid jets from the cross-jet nozzle channels 103 can be seen. In FIG. 3a, two cross-jet nozzle channels 103 are offset from one another in the transverse direction. A cross-jet nozzle outlet 1032 can be seen at the end of the cross-jet nozzle channels 103 . Here, too, an insert is usually inserted in order to increase the nozzle effect.

Along the section line marked with two arrows in FIG. 3a, the longitudinal section through the rotor body 10 according to FIG. 3b is shown in section, with one of the two cross-jet nozzle channels 103 being shown in detail in section. In addition to the recessed concentric feed channel 101, a branch channel 102 is branched off and part of the at least one radial nozzle channel 105 is shown. The cross-jet nozzle channel 103 is a continuous recess, running in a curved manner without edges, comprising an inlet section 1030 , a guide section 1031 and the cross-jet nozzle outlet 1032 . The cross jet nozzle channel 103 is curved overall to the longitudinal axis L and forms an arc.

In the assembled state of the rotor body 10 10 fastening means are arranged at the level of the stator body tip 205 of the stator body 20 along the side wall of the feed channel 101 in the rotor body. This area is marked with the dashed circle in Figure 3b. The fastening means on the rotor body 10 prevent a linear movement of the rotor body 10 relative to the stator body 20, with the rotational movement around the longitudinal axis L being possible without any problems.

The fastening means indicated in FIG. 3b can be seen more clearly in FIG. 3c and are identified by reference numeral 1010. The fastening means 1010 are provided in the side wall or along the side wall of the feed channel 101 within the rotor body 10, are therefore part of the rotor body 10 and are formed onto it or are recessed from it. The fastening means 1010 protrude at least partially towards the center of the feed channel 101, in the direction of the longitudinal axis L, into the feed channel 101 in part.

The fastening means 1010 form a snap closure or a latching closure, since the fastening means 1010 can be operatively connected to an annular groove 2050 on the stator body tip 205 and engage in an undercut H on the annular groove 2050 by snapping.

Here are in the edge region of the feed channel 101 fasteners 1010 in the form of, the feed channel 101 partially surrounding tongues or webs formed or recessed. The front area of the tongue or the web, which protrudes into the feed channel 101, snaps into place in the annular groove 2050 when the stator body 20 is mounted.

The recessed fastening means 1010, which partially protrude into the feed channel 101, partially engage in the annular groove 2050 on the stator body tip 205, so that when the rotor body 10 is in the assembled state, a linear movement parallel to the longitudinal axis L is successfully prevented. From the prior art, fastening means had to be loosely connected to the rotor body, which is solved differently here. As a result, simplified assembly of the rotor body 10 on the stator body 20 is possible.

The rotor body 10 is made of metal by means of additive manufacturing processes or 3D printing. 3D printing methods are known in which metals or metal powder are applied layer by layer and connected. Precise configurations, above all of the fastening means 1010 and the internal cross-jet nozzle channels 103, are thus possible, with the fastening means 1010 being able to be integrated into the rotor body 10, which happens layer by layer in additive manufacturing.

A 3D printing is possible today with high precision and corrosion-resistant cleaning nozzles, pipe cleaning nozzles and cross-jet cleaning nozzles 1 or associated rotor body 10 can be made of metal. Techniques such as laser beam melting, electron beam melting and laser sintering are used for the 3D printing of metals and metal alloys.

A cross-jet nozzle channel 103 with a special shape is also possible through additive manufacturing, the course and diameter of which can vary as desired. From the branch duct 102, which can also be omitted, the cross-jet nozzle duct 103 is cut out here as a continuous cut-out, running in a curved manner, comprising an inlet section 1030, a guide section 1031 and the cross-jet nozzle outlet 1032. The cross jet nozzle channel 103 is curved overall to the longitudinal axis L and forms an arc.

Inlet section 1030, guide section 1031 and cross-jet nozzle outlet 1032 have different curvatures relative to the longitudinal axis L. The angle of the center of the cross-jet nozzle channel 103 relative to the longitudinal axis L runs without discontinuities or jumps. The sections 1030, 1031 and 1032 preferably also have different diameters.

In practice, the cross jet cleaning nozzles introduced here are preferably attached to a lance of a lance device in order to apply cleaning fluid to them and to use them for cleaning pipes. If several lances are each equipped with a cross-jet cleaning nozzle, several pipes or pipe bundles can be cleaned easily and automatically by passing the lances through. In a further embodiment, the stator part 20 can be designed as part of the lance of the lance device.

reference list

[0029] 1 cleaning nozzle / pipe cleaning nozzle / Kreuzstrahlreinigungsdüse 10 rotor body 101 supply channel 1010 fasteners 102 branch channel (in the rotor body, zenral) 103 Cross jet nozzle channel 1030 inlet portion 1031 guide portion 1032 Kreuzstrahldüsenauslass 104 Front Beam Channel / Fronstrahldüse 105 radial nozzle channel 20 stator 200 feeding section 201 Statorzuführkanal 202 recoil nozzle channel (operations not shown) 203 Rotor body bearing 204 Central outlet 205 Stator body tip 2050 Ring groove D Nozzle tip L Longitudinal axis V Feed direction H Undercut

Claims (11)

1. Rotor body (10) of a pipe cleaning nozzle (1), comprising a feed channel (101) and branching off from it a branch channel (102) with a plurality of outlet channels, characterized in that the rotor body (10) is made of metal by means of an additive manufacturing process or 3D printing and fastening means (1010) are formed directly on the rotor body (10) or are recessed. 2. Rotor body (10) of a pipe cleaning nozzle (1) according to claim 1, wherein along the side wall of the feed channel (101) in the rotor body (10) fastening means (1010) at least partially to the center of the feed channel (101), into the feed channel (101) partially projecting in the direction of a longitudinal axis (L) such that an edge area of the fastening means (1010) can engage in an annular groove (2050) of a stator body tip (205) of a stator body (20), the rotor body (10) being detachably attached to the stator body (20) is operatively connectable. 3. Rotor body (10) according to any one of the preceding claims, wherein the fastening means (1010) have been recessed from the rotor body (10) during additive manufacturing and form an integral part of the rotor body (10). 4. Rotor body (10) according to one of the preceding claims, wherein the fastening means (1010) with the annular groove (2050) form a snap closure in that the fastening means (1010) can snap into an undercut (H) on the annular groove (2050). 5. Rotor body (10) according to one of the preceding claims 2 to 4, wherein the fastening means (1010) formed in the edge region of the feed channel (101) are designed in the form of tongues or webs partially projecting into the feed channel (101). 6. cleaning nozzle (1) with a rotor body (10) according to any one of the preceding claims. 7. Cleaning nozzle (1) according to claim 6, which is designed as a cross-jet cleaning nozzle (1) and has at least two cross-jet nozzle channels (103) branched off from the feed channel (101), each cross-jet nozzle channel (103) having an inlet section (1030), a guide section (1031) and a cross-jet nozzle outlet (1032), recessed within the rotor body (10) with different orientations relative to a longitudinal axis (L), so that a cleaning fluid can be transported from the supply channel (101) to a nozzle tip (D) and can be discharged there from the cross-jet nozzle outlet (1032 ) can be output. 8. Cleaning nozzle (1) according to claim 7, wherein the entire cross-jet nozzle channel (103) is made seamless without individually attached linear bores forming the cross-jet nozzle channel (103). 9. Cleaning nozzle (1) according to claim 8, wherein during operation cleaning fluid can be dispensed completely through the cross-jet nozzle channel (103) in a curve up to the cross-jet nozzle outlet (1032) from the nozzle tip (D). 10. Manufacturing method for manufacturing a rotor body (10) of a pipe cleaning nozzle (1) according to one of claims 1 to 5, wherein the rotor body (10) is made entirely of metal by means of additive manufacturing methods or 3D printing and is along the side wall of the feed channel (101 ) in the rotor body (10) fastening means (1010) at least partially to the center of the feed channel (101), in the feed channel (101) partially in the direction of a longitudinal axis (L) are firmly formed. 11. Lance of a lance device for cleaning tube bundles, wherein at least one cross jet cleaning nozzle (1) with a rotor body (10) according to one of claims 7 to 9 is arranged and used.