DE3448235C2 - - Google Patents

Description

The invention relates to a suitable as a root cutter Tool attachment for a, in particular a drive kende, recoil nozzle drive device for Rei nigen of pipes or the like., With the drive device with a hydraulic motor to drive the tool attachment an overpressure fluid jet arranged in a stator drivable rotor is provided, on which with the rotor shaft-connected tool attachment at least in the circumferential area cutting in the direction of advance or rotor axis teeth are provided.  

Rotating drives for tools are known per se. Out the US-PS 26 92 752 is connected to a garden hose Its stator and rotor drive for a tube Cleaning tool known in which a hydraulic drive interacts with a tool head. The tool head described as suitable for cleaning pipes ben and instructs a number on the driven shaft different cutting discs and has at the end of the shaft a milling head with a large number of burr-shaped, teeth set on gap. This tool will used to remove fat deposits and digested sludge. Hard incrustations can be found across the entire cross section do not remove, compliant, in a pipeline or in Canal ingrown roots are from such a plant not cut, but at most take it away cracked; they wrap around shaft and cutting discs and let the device become ineffective. One also as Root cutter suitable tool attachment is in DE-OS 21 22 498 described by a hydraulic motor in Form of interacting gerotor gears on two roto ren is driven. The tool attachment is up and on the free end of the driven shaft fixed there and points to connection with the drive wave a hub, from which a spiral saw blade term "root knife" with a free-standing end. The number voltage of the sawtooth-like knife is only in the circumference richly arranged. These teeth are said to be the wall of the pipe scrape off and descaling deposits, the Effect of the tool as a "root knife" apparently from the The idea is that when the wall is scraped off the pipe ingrown roots through the pipeline would cut. However, considering the lan cleaning intervals for underground ducts massive root ingrowth must be expected roots cut so long that they are in the tool  procedure and the proper operation of the cleaning hinder direction and let the speed drop. As a fol This also reduces to the free-standing end centrifugal force acting on the root knife, so that this does not more is pressed against the pipe wall, so that ingrown Roots (and also hard incrustations) to lift off the Lead root knife. The constant radial movements lead at the clamping point in the area of the hub to a permanent bend interchangeable stress leading to an uncontrollable break of the tool. Because the tool in underground Channels work unattended and cannot be checked visually tends to break the tool - if it does at all the feed necessary for cleaning is noticed - cause the cleaning device to be pulled out of the channel must be to renew the tool. An unnoticed bre Chen leads to the repair after supposed completion the pipe cleaning takes place and the pipe cleaning is repeated must become. One captured the entire cross section of the pipe Send cleaning is not possible with this tool.

This is where the invention comes in with such a tool header should be further developed so that it is a trace-free Revision of the entire cross-section to be treated leaves without being trained for large-area cutting be effective and without ingrown roots wise to be hindered so that braking of the drive to a standstill (blocking of the drive) by material chunks and / or root pieces is avoided.

This object is achieved on the one hand by the invention the characterizing part of claim 1; an alternative solution be writes the characteristic of claim 2. Advantageous Next Formations are the subject of dependent claims 3 and 4.  

The invention is based on the knowledge that an effective full cleaning of a pipeline or a duct in particular massive root growth is only possible if the entire cross section is covered. In addition, de recognized that capturing the entire cross-section to egg leads to constant alternating stress on the cutting knife, a stress that according to the invention by the Festle excluded from the cutting knife on the base plate becomes. Due to the spiral shape in the first embodiment the cutting knife, which are at an angular distance from each other are staggered on the base plate and the are provided with cutting teeth over their entire length with each revolution of the rotor over the entire cross section deleted. The hub area is also included, because the hub because of the base plate arranged under this that can and so there is room for the introduction of the cutting knife to the center. The arrangement can result in more The spiral arms are used to position the teeth in such a way that the teeth of the successive knives against each other puts a trace-free revision of the whole to behan Enabling cross-section. As a result of this spiral shape only part of the cross to be machined cut, only when rotating - one after the other - all cross-sectional areas affected.

In the second embodiment, the tool attachment has min at least two eccentrically suspended pens on the base plate the knife with the cutting in the direction of advance teeth are provided. With the help of the incisors are through the driven tool grooves into the material to be drilled milled. Once the material remaining between the grooves Grind the webs on the shaft of the pendulum knife the pendulum knife back so that the cutting teeth make their way leave and thereby the material webs from the sides mill away or tear off. Through this occur in intervals  commuting, the speed of the drive is hardly reduced, so that this continuously with significantly less power gets along with other known tools. Reached this will be achieved by significantly reducing the size of each Drilling area up to about half in the proposed Embodiments of the tool. Although the pendulum is attached to a rotating part for the purpose of Pipe cleaning known from US-PS 38 48 289, however in the tool proposed there, only the pipe scraped off the wall, whereby due to the special type of hanging oval pipes can also be cleaned. A treatment development of the entire cross-section with the one proposed there Device is not possible. This also applies to the proposal according to US-PS 20 38 004, in which the radially outwardly movable Baking during operation of the tool attachment by centrifugal force be pressed outwards against the pipeline and with ih other forward-facing cutting teeth have crusts of remove the pipe wall.

In order to achieve an additional cutting or removal effect, the base plate is cross-shaped and it will be the edges of the arms of the cross preceding in the direction of rotation provided with cutting edges. It has proven to be advantageous if bulges near the outer edges as a catch len are intended for roots, which ultimately the after root strands on the outward and on the slip other.

To center the tool attachment and if necessary also to the front He can drill with a protruding drill tip be. This is particularly useful for the pendulum knife Tool where the pendulum teeth are the central drilling area not quite grasp.  

In Figs. 1 exemplified to 4; it shows

Fig. 1 shows a longitudinal section through a drive tool,

Fig. 2 is a plan view of a tool having spirally guided knife,

Fig. 3 is a plan view of a tool with a pendulum knife and

Fig. 4 is a pivoted by 90 ° view of the arrangement of FIG. 1.

An advantageous tool drive according to FIG. 1 is provided with a rotor 2 arranged in a stator 1 , with four rows of blind holes lying axially next to one another, each blind hole row being provided with material holes 3 arranged offset around the rotor circumference. The rotor 2 is inserted from the front into the gate 1 and rotatably connected to the stator 1 via ball bearings 13 . The ball bearings 13 are held by a holding plate 18 by means of screw 19 . A seal 32 provided between ball bearing 13 and stator 1 protects the ball bearing by penetration of pressure medium supplied to drive the stator through the gap between rotor 2 and stator 1 . The feed pipe 10 for the drive pressure medium is introduced into the stator 1 on the left side and welded to it. At the rear, that is the left end, a nozzle holder 9 with recoil nozzles 8 is firmly connected to the feed pipe 10 . On the nozzle holder 9 , the pressure medium supply hose can be attached by means of a thread. So that the hose connection thread is secured against loosening by the counter-torque of the stator, the connection thread must be opposite to the direction of rotation of the rotor. On the left part of the stator 1 is a sleeve 21 with screw ben 22, a guide cage 20 is attached easily replaceable. On the rotor 2 , a base plate 15 for the tool 12 to be driven , here a saw blade, is fastened with screws 23 on the right .

The pressure medium supplied via the pressure medium supply hose for driving the stator flows out of the supply tube 10 via ra diale passages 14 and longitudinal passages 17 to the nozzle-like channels 4 , in which insert sleeves can be provided and then directly into the blind holes 3 . The blind holes are closed on the sides; the pressure medium is therefore deflected by the impact by 180 ° and can then only emerge radially through circumferential slots. As a result, an effective conversion of the energy supplied with the pressure medium into rotational energy is achieved, so that tools connected to the rotor can be operated advantageously, it being understood that other drives can also be used.

Fig. 2 shows the tool 12 as a spiral-like ge shaped knife that it cuts the entire cross section to be treated with rotation. It is attached to the cruciform base plate 15 , which in turn can be connected to the rotor via the screw holes 24 (and the screws 23 - FIG. 1).

FIGS. 3 and 4 show two different designs with oscillating blade 25 with cutting blades 25 in their working position. Directed from the vertical center line of Fig. 3 45 ° downward to the right, there is a shaft as a rectangular fair beams. This has the part before that the milled or chipped chunk of material can be particularly well through to the back and transported away due to its small width. In the event of resistance, it swings out slightly due to its low mass.

From the vertical center line of FIG. 3, directed 45 ° to the top left, there is a shaft as a triangular knife bar. The advantage of the triangular knife bar lies in its mass. It is particularly suitable for drilling or knocking off harder material and it does not swing out so quickly when it comes into contact with material. In addition, the entire drill is heavier and thus prevents the drill from rebounding when it comes into contact with the material.

The shaft of the knife 25 is pivotally attached to retaining bolts 27, which are centrally attached to the base plate 15, by means of cover disks 28 and nuts 29 . When the rotational speed decreases, the knife pivots in the direction of the pendulum radius 31 , whereby the bridges of the material left by the individual knife blades 26 are eliminated.

In the tool arrangement according to FIGS . 2 to 4, a pre-drill 30 known per se is arranged.

The cross-shaped base plate 15 , in particular in the case of a spiral-shaped saw blade, must correspond in its outer dimensions to the respective tube diameter, so that the saw blade having the saw teeth can be welded to the outermost diameter thereof. The edge in the longitudinal direction at the front of each bar of the cruciform base plate 15 can, as far as it projects beyond the rotor diameter, be ground and bulges 34 can be provided on the outer circumference as a rake angle. This keeps the tool in addition to the drilling function a cutting function, so that it acts as a root cutter.

Claims (4)

1. As a root cutter, suitable tool attachment for a recoil nozzles, in particular, effecting propulsion, pointing drive device for cleaning pipes or the like wherein on the ver with the rotor shaft connected tool attachment at least in the circumferential area in the direction of advance or rotor axis, cutting teeth are provided, characterized in that the tool attachment has a non-positive and / or positive-locking base plate ( 15 ) connected to the rotor ( 2 ) , following the spiral in the center of the barrel, following in parallel, offset by the same angle from each other, at least two known saw blade-like cutting knives ( 12 ) and at least in the middle and edge area by welded connections to the base plate ( 15 ) are firmly connected, the base plate ( 15 ) corresponding to the pipe diameter in wesent union, and wherein the edges of the cutting blade ( 12 ) facing away from the base plate ( 15 ) are provided with cutting teeth over their entire length. 2. Suitable as a root cutter tool attachment for a recoil nozzles, in particular, causing propulsion, pointing drive device for cleaning pipes or the like, the drive device being provided with a hydraulic motor for driving the tool attachment via a rotor arranged in a stator and drivable via pressurized fluid jets, and wherein on the tool attachment connected to the rotor shaft, at least in the circumferential region in the direction of advance or rotor axis, there are provided cutting teeth, characterized in that the tool attachment has a base plate ( 15 ) which is non-positively and / or positively connected to the rotor and on which a preferred Wise multi-part cutting knife ( 25 ) with cutting teeth ( 26 ) pointing in the direction of advance by means of a bolt arrangement ( 27 ) arranged eccentrically to the rotor axis, about a pivot axis lying parallel to the rotor axis, is pivotally suspended on the base plate ( 15 ), the base plate ( 15 ) and the cutting knife ( 25 ) in the state stretched by centrifugal force substantially correspond to the tube diameter. 3. Tool attachment according to claim 1 or 2, characterized in that the base plate ( 15 ) is cross-shaped and the leading in the direction of rotation edges of the arms of the cross ground like a knife and preferably near the outer edges are provided with bulges ( 34 ). 4. Tool attachment according to one of claims 1 to 3, characterized in that the base plate ( 15 ) is provided concentrically with the rotor axis with a pilot drill ( 30 ).