DE202015001636U1 - Drilling machine for pipe cleaning - Google Patents

Abstract

Drill (1) for pipe cleaning comprising a stator (10) and a rotor (20) with a milling head (25) wherein the rotor (20) on an axis (X) of the stator (10) is storable and the rotor (20) Actuation of the drill (1) with a fluid (F), in particular recycled water by rotation of at least one exiting fluid jet (FS) is driven by rotation, characterized in that the stator (10) at least one of the axis (X) and spaced from the rotor (20) is arranged separately arranged rotor drive line (7) having an opening (8) at the rotor end such that a turbine-like drive of the rotor (20) upon application of the rotor drive line (7) with the fluid (F) can be formed, wherein the fluid (F) from the opening (8) of the at least one rotor drive line (7) of the stator (10) in the form of a fluid jet (FS) emerging on a plurality on the rotor (20) arranged baffle elements (22) aligned, whereby the rotor ( 20) indirectly d urch the fluid from the rotor drive line (7) exiting fluid jet (FS) is driven.

Description

Technical area

The present invention relates to a drill for pipe cleaning according to the preamble of the first claim.

Pipe cleaning refers to the activity of cleaning and maintaining pipelines. In particular, such drill cutters are used for pipe cleaning for milling work of deposits such as concrete, injection and lime in clogged pipelines.

State of the art

Known from the prior art drill milling for pipe cleaning, which are operated with a pressure medium such as water. Water as the pressure medium to drive is advantageous, for example, with respect to an electric drive, where it may come to an electrical short circuit due to the presence of water in the pipeline. Such boring machines usually include a stator and a rotor with a milling head, wherein deposits are removed in the pipe by rotation of the rotor through the milling head.

Out EP 0 077 562 A2 is a pipe cleaning device designed as a drill for sewer lines known which is operated by means of water as a pressure medium. From EP 0 077 562 A2 known drill includes a stator and a rotor with a milling head. The rotor of the pipe cleaning device is mounted on an axis of the stator.

In addition, the pipe cleaning device EP 0 077 562 A2 a supply line for a fluid, wherein via a central bore in the stator pressurized water can flow.

In the case of the cleaning device embodied as a drill, the pressure medium or the pressurized water subsequently leaves the stator through radial bores and flows into the rotor. In the transition region between the stator and the rotor, a fluid bearing or a floating bearing is formed in the drill, wherein the rotor can rotate liquid-supported both at its front and at its rear radial bearing.

This known pipe cleaning device has the disadvantage that the necessary for milling rotation of the rotor is achieved by a complex fluid guide. The milling head of the rotor obliquely directed to the side recoil nozzles or radially outward and sideways directed radial nozzles require a complicated manufacturing of the rotor.

Due to the almost inevitably resulting from the arrangement fluid storage in a transition region between the stator and rotor as a further disadvantage, the fluid must be as pure as possible or may hardly contain dirt particles, which can lead to increased internal friction in the radial bearings or even have an abrasive effect. In addition, in such a case would be necessary replacement of the radial bearing from the drill from EP 0 077 562 A2 associated with special effort.

Furthermore, it is off CH 686 732 A5 a configured as a drill cutter pipe cleaning device, comprising a milling head suitable for cleaning, for example, completely clogged with concrete pipes. The drill from CH 686 732 A5 has a stator with a guide carriage. The guide carriage comprises a holding tube, which receives a supply tube or a supply line for a fluid inside.

In addition, on the rotor designed as a drill cutter pipe cleaning device CH 686 732 A5 also a milling head attachable.

Front side, d. H. towards the milling head, the supply tube takes on the rotor as the central stator axis, whereby the rotor is rotatably mounted on the axis of the stator.

Furthermore, the pipe cleaning device off CH 686 732 A5 near the front end of the supply line openings arranged in the wall. Through these openings, the pressure medium in the area between the rotor and feed tube, ie stator, pumped and serves a low-friction storage. Thus also rejects the pipe cleaning device CH 686 732 A5 in a transition region between the rotor and stator, a fluid bearing with the disadvantages described above.

To generate the rotation of the rotor, the pipe cleaning device is off CH 686 732 A5 formed such that the pressure medium from the transition region via respective arms of a hub having the shape of a tubular piece of the rotor passes to recoil nozzles. From these recoil nozzles, the pressure medium leaves the rotor tangentially and thereby puts it into rotation. The pipe cleaning device off CH 686 732 A5 thus has a direct drive of the rotor. By using the fluid bearing and freely branched supply lines of the pressure medium inside the rotor, such a cleaning device should only be operated with fresh water.

Presentation of the invention

The present invention has for its object to provide a drill for pipe cleaning, which in a simple way hydraulically, especially with dirt particles exhibiting recycled water is operable.

This object is achieved by a drill for pipe cleaning with the features of claim 1.

Further advantageous embodiments are specified in the dependent claims.

The drill according to the invention for pipe cleaning comprises a stator and a rotor with a milling head. The rotor can be stored on an axis of the stator. Furthermore, when the drill is loaded with a fluid, in particular recycled water, the rotor can be driven in rotation by generating at least one outgoing fluid jet.

According to the invention, at least one rotor drive line spaced from the axis and separated from the rotor is mounted on the stator with an opening at the rotor end such that a turbine-like drive of the rotor can be formed when the rotor drive line is exposed to the fluid. Furthermore, the fluid can be released from the opening of the at least one rotor drive line of the stator in the form of a fluid jet and aligned with a plurality of impact elements arranged on the rotor, whereby the rotor can be driven indirectly by the fluid jet emerging from the rotor drive line.

Such a resulting, turbine-like drive by means of rotor drive line on the stator and baffles on the rotor has the advantage that not necessarily pure water must be used, but also recycled, dirty water, d. H. Also dirt particles containing water can be used. Thus, the inventive drill is hydraulically operable in a simple manner and in particular recycled water used.

Furthermore, by the pressure medium from the rotor drive line, an indirect, turbine-like power transmission to the rotor, which is particularly effective.

For the purposes of the present invention, an indirect rotor drive means that no water passes through the rotor. The rotor must accordingly have no fluid-carrying supply lines. In this context, the type of drive according to the invention is independent of the bearing of the rotor on an axis of the stator. As a result, any desired bearing of the rotor relative to the stator can be advantageously selected.

In the further description, the term "front side" denotes the side of the milling head or the side facing the pipeline to be cleaned. The term "back side" refers to the side from which the cleaning device is guided into the pipeline.

Preferably, the baffles of the rotor, for example, carbide.

Preferably, the inventive drill is designed for a pressure of the pressure medium in a pressure range of a few to several hundred bar.

For the purposes of the present invention, the pipe cleaning device may be a drill with or without impact pulse, d. H. a drill that can perform in addition to the normal rotational movement and a vibration-like movement in the axial direction.

Such impact pulses have the advantage in principle that the deposits to be milled are already made (somewhat) brittle by the generated hammer-like impact. As a result, the milling performance, especially when milling hard obstructions in the pipes to be cleaned, greatly increased.

In terms of a preferred embodiment of the invention, the pressure medium water is used in addition to the drive of the rotor of the rinse resulting abrasion.

Preferably, the rotor is integrally or multi-piece configured comprising a hub, a milling head and a ring member.

In principle, different positions and orientations of a respective impact element on the rotor are conceivable for the formation of the turbine-type drive, so that the fluid from the rotor drive line of the stator emerges from the impact element in such a way that a force transmission from the pressure medium to the rotor and a resulting rotation of the rotor is reachable.

Preferably, baffles of the plurality of baffles at least partially faces the axis of the stator. It is conceivable, for example, for the plurality of baffle elements to be formed freestanding on the rotor.

Particularly preferably, the plurality of impact elements is formed on or in the ring element or designed. Such an arrangement in the ring corresponds to a more stable design. In addition, the plurality of impact elements on a ring element which can be fixed on the rotor has the advantage that the ring element can be exchanged easily in the event of any baffle elements deformed by the pressure medium. It is also advantageously conceivable that individual impact elements can be fixed on the ring element and thus easily exchanged.

Alternatively, it is conceivable that baffles run through recesses arranged in the circumferential direction in the lateral surface of a cylindrical ring element, d. H. the baffles are separated by the recesses.

Most preferably, the plurality of baffles forms substantially in the direction of the axis of the stator extending cross braces of the ring member. This integral arrangement of the baffle elements in the ring element reduces the risk of deformation of the baffle elements by the pressure medium.

Preferably, the ring element is fixed or fixable on the rotor on the side facing the stator and the rotor drive line at least partially protruding into the ring element without contact in the direction of the axis of the stator.

Preferably, the drill has at least one supply line, which is arranged opening into the at least one rotor drive line.

Preferably, the supply line by means of a branching into the at least one rotor drive line opens and arranged branching, whereby the at least one rotor drive line forms a bypass to the supply line.

For the purposes of the present invention, the supply line is the back of the supply line of a pressure medium, such as water or the like. Preferably, the supply line passes back into a pipe or hose coupling, which serves for coupling a hose. For the purposes of the present invention, the supply of the pressure medium from a (high-pressure) pump via the hose into the supply line of the drill is directed.

It is possible for the supply line to open into two off-axis, opposite rotor drive lines. It is also possible that the supply line opens into three or more spaced apart from the axis rotor drive lines.

Furthermore, according to a preferred development of the invention, the opening of the at least one rotor drive line is designed as a nozzle or a nozzle is arranged in the opening. By means of a nozzle, the fluid jet can advantageously be better focused.

In principle, the impact element can be an arbitrarily designed body. Preferably, the baffle element is designed as a baffle plate.

A baffle surface of a respective impact element and the opening of the rotor drive line are preferably aligned with one another in such a way that the pressure medium impinges on at least one rotor position in a beam perpendicular to a respective baffle plane of the impact element. Alternatively, it is conceivable in this connection that the baffle surface has such a concave configuration instead of a plane that the pressure medium impinges on the baffle surface in a plurality of rotor positions in a jet.

By such an orientation of the opening on the baffle can advantageously be effected on each of a baffle surface of the impact element optimum force transmission of the pressure medium.

Preferably, each of the baffle plane of the baffle element to an radial plane of the annular ring element biases an angle of 25 ° to 65 °.

Such an angle is advantageously chosen so that in connection with the orientation of the opening of the rotor drive line as vertical as possible impact of the fluid jet is achieved on the baffle of a respective impact element.

Preferably, the opening of the rotor drive line is spaced from the baffles by preferably a few millimeters to a few centimeters.

Preferably, the rotor is mounted rotatably on the axis of the stator by means of a ball bearing.

In contrast to a floating bearing - as known from the prior art - when using a ball bearing is not on the quality of the fluid used as a printing medium, d. H. hardly any dirt particles, be respected, since the pressure medium does not serve for the storage.

Alternatively, other possibilities for rotatably supporting the rotor on the axis of the stator are conceivable, such as, for example, a gear with toothed wheels, etc.

Breakthroughs for passing the fluid are preferably formed between each two impact elements on the ring element.

Such breakthroughs in the ring member of the rotor advantageously allow passage of the Fluids to the inner wall of the pipe, so that at times when passing through the openings through the fluid, the abrasion can be washed away.

Preferably, the rotor is modular buildable. A modular rotor can be built up to the extent that individual elements, such as, for example, the ring element, which is particularly stressed during operation and subject to wear, can be exchanged in a simple manner.

Brief description of the drawings

A preferred embodiment of the subject invention will be described below in conjunction with the accompanying drawings. Show it:

1 a perspective side view of an inventive drill for pipe cleaning

2 a longitudinal section through a drill according to the invention for pipe cleaning

3 a cross section through a ring element of a drill according to the invention for pipe cleaning with an impinging on a baffle fluid jet

4 a cross section through a ring element of an inventive drill for pipe cleaning with exiting fluid jet

description

1 shows a perspective side view of an inventive drill 1 for pipe cleaning. The drill according to the invention 1 is divided into a stator 10 and a rotor 20 with a milling head 25 and is modular buildable. The drill according to the invention 1 out 1 can be dimensioned for use in pipelines 2 with a diameter of ≥ 200 mm or ≥ 300 mm, in particular up to a maximum diameter of 600 mm. By a generated rotation of the rotor 20 in a circumferential direction U and a linear propulsion L clogging deposit V in the pipeline 2 eliminate it.

The milling head 25 has the shape of a plate-shaped carrier, which can be provided with milling elements at suitable locations. The cutting elements are tooth-like designed elements of known type of hard metal, diamond or other suitable materials. The rotor 20 is divided into a hub 24 , a milling head 25 as well as a ring element 21 , which can be fixed together, for example screwed together, are modular or can be built up. At a front end of the pipe section 26 the hub 24 is a pre-cutter 27 fixable. On the ring element 21 are a multitude of breakthroughs 23 can be seen, which are designed here as a slot. According to 1 includes the drill according to the invention 1 in the following a guide carriage 30 which is the stator 10 framed, with six, in the circumferential direction regularly spaced guide runners 31 , Moreover, in 1 it can be seen that in each case at a Führungskufe 31 two rollers on the front 32 as well as two rollers on the back 32 are attached. By means of adjusting plates 33 are the lead skids 31 radially displaceable in the direction of arrow P ₁ or correspondingly adjustable to the diameter of the pipeline 2 ,

As in 1 can be seen, the drill according to the invention 1 on the back a hose connection 6 on which with a supply line - as in 2 visible - pressure-tight connectable. With the hose connection 6 is again a hose 4 connectable, with the hose 4 the supply of water as a pressure medium from a high-pressure pump via the hose 4 into the supply line (cf. 2 ) the drill 1 serves.

2 shows a longitudinal section through a drill according to the invention 1 for pipe cleaning. The rotor 20 is rotatably mounted on an axis X of the stator 10 by means of a ball bearing 15 ,

As in 2 Obviously, the rotor is divided 20 in a hub 24 , a milling head 25 as well as a ring element 21 , which are fixable with each other. In addition, the hub has 24 a pipe section 26 on, which by a central recess of the milling head 25 can be guided on the front side. Inside, ie in the direction of the axis X of the stator 10 , are on the ring element 21 a variety of impact elements 22 arranged. The ring element is on the stator 10 facing side along a cross section BB on the rotor can be fixed. The ring element 21 has a cylindrical ring element wall 34 as well as a ring hole 35 on. The ring element wall 34 runs substantially parallel to the axis X of the stator 10 , In this ring element wall 34 is a variety of breakthroughs 23 arranged, which allow passage of the fluid jet F _S. Through such breakthroughs 23 , which passage of the fluid up to the pipe inner wall of the pipeline (see 4 ), this can be the ring element 21 passing fluid F temporarily the abrasion of the pipe inner wall of a pipeline 2 wash away. At the ring wall 34 are the baffle elements 22 formed. Moreover, in 2 seen that between the breakthroughs 23 the trained impact elements 22 as substantially in the direction of the axis X of the stator extending cross struts of the ring element 21 serve.

In the following shows the drill according to the invention 1 out 2 two rotor drive lines 7 . 7 ' each with an opening 8th , The at least one rotor drive line 7 . 7 ' protrudes into the ring hole 35 of the rotor 20 fixed ring element 21 partly in the direction of the axis X of the stator 10 or forms an overlapping area to the ring element wall 34 , Here are recesses 28 in the hub 24 sure that the at least one rotor drive line 7 . 7 ' the rotor 20 not touched. By this arrangement is advantageous the spacing between the opening 8th the at least one rotor drive line 7 . 7 ' and impact element 22 kept low for improved power transmission from the fluid F as the pressure medium. Furthermore, the front side of the supply line 5 breakthroughs 23 formed towards the milling head, for washing away the abrasion on the milling head 25 or cooling of the cutting elements on the milling head 25 , Due to the in 2 shown parallel arrangement of the rotor drive lines 7 . 7 ' to the supply line 5 can the at least one rotor drive line 7 . 7 ' as a bypass to the supply line 5 be understood.

For operating the drill according to the invention 1 becomes the drill 1 over the hose connection 6 to a hose 4 connected, while in turn the hose 4 is coupled with a high-pressure pump pressure-tight for supplying a fluid F. In a further step, the drill is acted upon with fluid F as a pressure medium. The course of the fluid F as a pressure medium in the drill 1 is indicated by the arrows P ₂ . The fluid F comes from the hose connection 6 into the supply line 5 and over a branch 11 in the rotor drive line 7 , Out of the opening 8th the rotor drive line 7 . 7 ' of the stator 10 occurs the fluid F in the form of a fluid jet F _S and hits by appropriate orientation of the opening 8th on the baffles 22 , causing the rotor 20 is driven or rotated. Due to the generated rotation of the rotor 20 including the milling head 25 and a linear feed will be the pipeline 2 Clogging deposits V milled away.

For the propulsion of the drill according to the invention 1 known means may be used, such as a drawbar. Furthermore, the drill according to the invention can be provided with means for generating a shock pulse such as cams. Furthermore, it is optionally possible that on the free-standing part of the stator 10 Flush lines are available for Wegspülen incurred abrasion. Optionally available on the rotor 20 freestanding impact elements 22 be formed.

Furthermore, based on the 3 and 4 relevant parameters explained to the power transmission from out of the rotor drive line 7 escaping pressure medium on the baffles 22 for rotation of the rotor 20 to optimize.

3 schematically shows a cross section along in FIG 1 shown line AA through a ring element 21 a drill according to the invention 1 for pipe cleaning, wherein a fluid jet F _S from the rotor drive line 7 out of the opening 8th exiting on a baffle 29 of the baffle element 22 impinges, causing the rotor 20 indirectly by the exiting fluid F from the rotor drive line 7 in the direction of rotation U can be driven. The variety of impact elements 22 on the ring element 21 ensures the maintenance of the drive. According to 3 is a nozzle in the opening 9 arranged. In addition, that is in the opening 8th the rotor drive line 7 arranged nozzle 9 aligned so that the fluid F in the in 3 shown rotor position in a fluid jet F _S perpendicular to a respective plane P of the baffle 29 incident. In such a rotor position, the power transmission is optimized starting from the fluid F. The opening 8th the rotor drive line 7 is from the baffle element 22 spaced by a distance s of 10 to 20 mm. The plane P of the baffle 29 a respective impact element 22 and a radial plane R of the circular ring member 21 span an angle α of around 45 °.

4 schematically shows a cross section along in FIG 1 shown line AA through a ring element of an inventive drill 1 for pipe cleaning in a different rotor position than in 3 with escaping, a breakthrough 23 of the ring element 21 passing fluid jet F _S , which thereby on the pipe inner wall of the pipeline 2 can impinge, so that by the fluid F, the abrasion can be washed away.

The diameters of the rotor drive line 7 , the feed line 5 and the nozzle 9 the drill according to the invention 1 are chosen such that they are easily consistent for recycled water and long operating times of the inventive drill 1 possible are.

LIST OF REFERENCE NUMBERS

1

fraise

2

pipeline

4

tube

5

supply line

6

hose connection

7

Rotor drive line

8th

opening

9

jet

10

stator

11

branch

15

ball-bearing

20

rotor

21

ring element

22

baffle

23

breakthrough

24

hub

25

milling head

26

pipe section

27

roughing

28

recess

29

baffle

30

guide carriage

31

guide runner

32

role

33

Adjustable Plates

34

Ring element wall

35

ring hole

X

Axis (stator)

F _S

fluid jet

P

Plane (baffle)

U

direction of rotation

V

Clogging deposit

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 0077562 A2 [0004, 0004, 0005, 0008]
• CH 686732 A5 [0009, 0009, 0010, 0012, 0012, 0013, 0013]

Claims (10)

Drill bit ( 1 ) for pipe cleaning comprising a stator ( 10 ) and a rotor ( 20 ) with a milling head ( 25 ) wherein the rotor ( 20 ) on an axis (X) of the stator ( 10 ) is storable and the rotor ( 20 ) when applying the drill ( 1 ) with a fluid (F), in particular recycled water, by generating at least one exiting fluid jet (F _S ) is driven in rotation, characterized in that on the stator ( 10 ) at least one spaced from the axis (X) and from the rotor ( 20 ) separately arranged rotor drive line ( 7 ) with an opening ( 8th ) is mounted at the rotor end such that a turbine-like drive of the rotor ( 20 ) upon application of the rotor drive line ( 7 ) is formed with the fluid (F), wherein the fluid (F) from the opening ( 8th ) of the at least one rotor drive line ( 7 ) of the stator ( 10 ) in the form of a fluid jet (F _S ) exiting a plurality on the rotor ( 20 ) arranged impact elements ( 22 ) aligned, whereby the rotor ( 20 ) indirectly by the from the rotor drive line ( 7 ) exiting fluid jet (F _S ) is drivable. Drill bit ( 1 ) for pipe cleaning according to claim 1, characterized in that the rotor ( 20 ) in one piece or in several pieces, comprising a hub ( 24 ), a milling head ( 25 ) as well as a ring element ( 21 ) is configured. Drill bit ( 1 ) for pipe cleaning according to claim 2, characterized in that the plurality of impact elements ( 22 ) on the ring element ( 21 ) of the rotor ( 20 ) is arranged. Drill bit ( 1 ) for pipe cleaning according to claim 2 or 3, characterized in that the ring element ( 21 ) on the rotor ( 20 ) on the stator ( 10 ) facing side is fixed or fixable and that the rotor drive line ( 7 ) at least partially in the direction of the axis (X) of the stator ( 10 ) in the ring hole ( 35 ) of the ring element ( 21 ) is arranged without contact protruding. Drill bit ( 1 ) for pipe cleaning according to one of the preceding claims, characterized in that the drill ( 1 ) at least one supply line ( 5 ), which in the at least one rotor drive line ( 7 ) is arranged opening. Drill bit ( 1 ) for pipe cleaning according to claim 5, characterized in that the supply line ( 5 ) by means of a branch ( 11 ) into the at least one rotor drive line ( 7 ) is arranged opening, whereby the at least one rotor drive line ( 7 ) a bypass to the supply line ( 5 ). Drill bit ( 1 ) for pipe cleaning according to one of the preceding claims, characterized in that the opening ( 8th ) of the at least one rotor drive line ( 7 ) as a nozzle ( 9 ) or in the opening ( 8th ) a nozzle ( 9 ) is arranged. Drill bit ( 1 ) for pipe cleaning according to one of the preceding claims, characterized in that the rotor ( 20 ) by means of a ball bearing ( 15 ) rotatable on the axis (X) of the stator ( 10 ) is stored. Drill bit ( 1 ) for pipe cleaning according to one of claims 2 to 8, characterized in that between each two impact elements ( 22 ) on the ring element ( 21 ) Breakthroughs ( 23 ) are formed for passing the fluid (F). Drill bit ( 1 ) for pipe cleaning according to one of the preceding claims, characterized in that the rotor ( 20 ) modular construction.

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