WO1993005334A1

WO1993005334A1 - Inner treatment process and device for inaccessible pipes

Info

Publication number: WO1993005334A1
Application number: PCT/CH1992/000175
Authority: WO
Inventors: Alfred Morgenegg
Original assignee: Alfred Morgenegg
Priority date: 1991-08-30
Filing date: 1992-08-28
Publication date: 1993-03-18
Also published as: BR9205435A; JPH06501767A; FI931922A; CA2095143A1; NO931520L; FI931922A0; CZ73893A3; HUT67874A; AU2448892A; HU9301175D0; NO931520D0; EP0556358A1

Abstract

The process uses a remote-control robot (1) with a video-monitored working head (2). The part to be opened or repaired is cut out, or a pig is placed and inflated so as to be clamped in the pipe at the part to be sealed. The process is mainly characterized in that the desired cut-out part is sealed with a two-component epoxy resin. Both components are mixed in an opposite flow helical mixer just before reaching the working head (2), forming an intimate, curing epoxy resin mixture. The device has a front rotary disk wheel (9) arranged on the robot (1), that carries a fork (10) provided with an articulation (13). A pivotable and retractable working head (2) is mounted between the ends (11) of the fork. The working head (2) may be designed as a cutting unit (4), as an inflating unit for clamping pigs, as a pressing unit for pressing and smoothening epoxy resin, as a whirling unit for coating the inside of pipes or as a combination of such units.

Description

Method and device for internal processing of non-accessible conduit pipes

The present invention relates to a method and an apparatus for processing conduit pipes, for example sewer pipes, that cannot be accessed from the inside for renovation or other purposes. In particular, the invention allows lateral branches in such line pipes to be closed or opened and repairs to be carried out at damaged locations.

So-called sewer rehabilitation robots are known for this purpose, which include a small, elongated, self-propelled vehicle that can run in the conduit, the vehicle being designed as a robot by using processing tools, for example a milling head, as well as injection syringes and fillers wearing. The robot vehicle is also equipped with a video camera and can therefore be operated from a supply and control unit, which are arranged above ground, are operated. The supply and control unit is usually permanently installed in a special vehicle, for example in a truck box body, in a truck box trailer or in an easily movable container. The milling cutter of the milling head is movable. With its help, a site to be renovated can be milled out under video observation, after which filler is sprayed from a cartridge, which is housed in the robot vehicle, into the milled-out area. Finally, the area is pressed and smoothed using a press shoe.

Conventional robots have various disadvantages which restrict their use or reduce their efficiency. Such a disadvantage can be seen, for example, in the fact that the milling cutter cannot act towards the front, but only sideways in relation to the elongated robot vehicle. In addition, for technical reasons, the milling cutters of conventional robots often have insufficient power or speed. After all, the robot vehicle often has to be pulled out of the pipe during longer work phases in order to replace the used cartridge with a new, full one. A lot of valuable time is lost during this time, during which the entire system, which is nevertheless a high investment, is paralyzed.

It is the object of the present invention to eliminate these disadvantages and to create a technically more mature method and a device for its practice which generally have broader technical application possibilities. Enable higher efficiency in the effect and in many ways implement better technical solutions for this.

The object is achieved by a method for the internal processing of inaccessible conduit pipes, in which a remote-controlled robot with a video-monitored working head, which is moved into the pipe conduit to be machined by a supply and control unit arranged above ground, the one to be opened or repaired Milled out place, or placed a pig at the point to be closed and braced by inflation in the conduit, the method being characterized by the characterizing features of claim 1.

Another aspect of the object is achieved by a method for the internal processing of inaccessible conduit pipes according to claim 1, in which the opening to be opened is milled with the characterizing method steps according to claim 2.

The object is finally achieved by a device for carrying out the method according to claim 1 or 2, with a remote-controlled robot which can be moved into the line pipe to be machined and has a video-monitored working head and an associated supply and control unit, the device being characterized by the characterizing features according to claim 3. The invention also permits machining toward the front, that is to say at a dead end of a conduit or at a blockage in the front. Due to the special technical design of the robot, it is particularly powerful and the processing is accordingly efficient and versatile. Much time can be saved by mixing the leveling compound by continuously feeding two components of an appropriate epoxy resin at the processing location. In addition, only as much filler is prepared as is actually used and no unnecessary waste is produced, as is inevitable when using cartridges, the content of which is often only partially consumed per operation.

The device according to the invention is described below with the aid of drawings of an exemplary embodiment and the function of the individual components is explained, so that the method according to the invention and its specific features and advantages can also be understood.

It shows:

Figure 1: A train composition of locomotive, control valve unit and robot;

Figure 2: The working head, here designed as a milling head, pivotally mounted between the fork tips, seen from above; FIG. 3 The milling head with milling cutter and the video camera, pivotally mounted in the likewise pivoting fork, seen from the side;

Figure 4: The milling head seen in a cross section from the side;

FIG. 5 the milling head between the fork end seen from the front with the sliding shafts, which make it possible to extend the milling head;

Figure 6: The pressing unit, mounted on the milling head;

Figure 7: The counter-rotating spiral mixer, partially cut open, seen from the side;

Figure 8: The synchronous drive of the locomotive with gear wheels.

1 shows all the essential components of the device according to the invention in an overall view. The device forms a train composition consisting of locomotive 8, control valve unit 14 and the actual robot 1. These individual composition elements 1, 8 and 14 are connected to one another via swivel joints 15, 16. The elements 1, 8 and 14 can thus be pivoted up and down to one another and sideways become. By means of these swivel joints 15, 16, the entire train composition is very mobile and it can also be used to negotiate the narrowest curve radii that may occur in sewer pipes. The locomotive 8 is responsible for shifting the entire train composition. To do this, it must be able to apply the greatest possible pulling or pushing force. For this purpose, it is equipped with a synchronous all-wheel drive, which works via four wheels 12 with special stud tires 28, which ensure good adhesion to the mostly wet and slippery inner walls of the conduit pipes. The drive takes place via a single electric motor housed in the locomotive 8 and will be described in more detail later. The supply and control lines 3, which can be approximately 200 meters long, run through the locomotive 8 and must be retightened by the locomotive 8 from the access shaft from which the composition is inserted into the conduit to be processed. These are three functionally different lines, namely an electrical control and feed line 33 for the electrical supply to the electric motor and for the control signals and measurement signals, and a pneumatic feed line 34, as well as supply lines for the processing to epoxy resin, namely two lines 35 for the two compo- ^• th of the epoxy resin. The lines 33, 34 and 35 lead through the locomotive 8 into the next front element, the valve control unit 14. In this valve control unit 14 a counter-rotating spiral mixer is accommodated, by means of which the two components of the epoxy resin are pressed through be intimately mixed. The structure and arrangement of this spiral mixer will be described in more detail later. In the drawing it can be seen that two lines 35 for the two components of the epoxy resin lead into the valve control unit 14, but only one 35, since the epoxy resin for processing is already completely mixed when exiting the valve control unit 14. The pneumatic feed line 34 leads from the valve control unit 14, although combined in a single tubular sleeve, branches into the actual robot 1, where the compressed air is required for various functions. The robot 1 consists of a cylindrical drive and control part 36. This is provided on the outside with skids 37 or wheels on which it slides or rolls in the conduit without being damaged. This cylindrical drive and control part 36 is of relatively heavy construction, since it has to absorb the reaction forces during processing and give the entire robot 1 the necessary stability. At the front of the cylindrical drive and control part 36, a plate disk 9 sits like an end cover. This plate disk 9 can be rotated about the longitudinal axis of the robot 1 via a gear drive by means of an air motor, specifically by up to 420 °. A fork 10 is mounted on this plate disk 9 and has a swivel joint 13. The actual working head 2 is pivotally arranged between the fork ends or fork tips 11. The working head 2 can be a milling unit 4 for milling conduit locations or as a blowing unit for bracing pigs, as a pressing unit 23 (FIG. 6) for pressing and smoothing of epoxy resin, as a centrifugal unit for internally coating pipes, or as a combination of such units 4; 23. In the example shown, the working head 2 is a milling unit 4 with a milling cutter 5. Behind the working head 2, a video camera 7 with a halogen lamp 21 is mounted between the fork 10, which can be pivoted there and can be fastened in any position. In practice, the train composed of locomotive 8, control valve unit 14 and robot 1 is usually pushed by hand from a shaft into a conduit to be processed. The setting of the pivot angle of the fork 10 at the fork joint 13 is adapted to the diameter of the line pipe to be processed. Thanks to this joint 13, about which the fork can be swiveled by approximately 60 °, pipes with an inner diameter of approximately 850 mm can be processed. The locomotive 8 pushes the robot 1 and the valve control unit 14 forward after the pushing-in of the train composition into the conduit to the desired processing point, which is monitored with video surveillance from the supply and control unit, that is to say from the day. The supply and control unit is advantageously housed in a truck box body, in a truck box trailer or in an easily movable container. The rest of the work can only be done from the control panel of this supply and control unit. When the robot 1 is pushed in, the locomotive 8 has to tighten the supply and control lines 3; 33-35, which is why a strong drive for the locomotive 8 is essential. The closer arrangement of the working head 2, here the milling unit 4, is shown in FIG. 2 in a view from above. This milling unit 4 is pivotally arranged between the fork ends 11. The drive for its motorized pivoting can be seen on one side of the milling unit 4. It is a gearwheel 39, in which a worm 41 engages, which is pneumatically driven by the drive and control part 36 of the robot 1, that is to say by an air motor. The power transmission can take place, for example, via cardan shafts with universal joints or via a string. The milling unit 4 can thus be moved into the desired swivel position under video surveillance, and the self-locking of the worm drive ensures good stability, so that the milling unit 4 can easily absorb the reaction forces of the machining in the set swivel position. The back of the milling unit 4 is rounded in accordance with the pivoting radius, so that it does not get stuck anywhere when the motor is pivoted.

In FIG. 3, the fork 10 with the milling unit 4 arranged in between is shown in a view from the side. The fork 10 is mounted on the plate 9, which can be rotated by 420 ° by means of an air motor via a gear drive. The plate 10 also rotates the fork 10 and the working head 2 arranged between its ends, here the milling unit 4. The fork 10 has a joint 13 around which the front part of the fork 10 is rotated by approximately 60 ° is pivotable upwards. Together with the rotation of the plate disk 9, this results in a further machining area for the working head or the milling unit 4, which describes a correspondingly large circle when the plate disk 9 rotates. Approximately in the longitudinal center of the fork 10 there is a compact, special video camera 7 with a halogen lamp 21, the swivel position of which is fixed in such a way that the objective 30 is directed approximately in the direction of the processing point. In order to keep the objective 30 clean during the milling work, a water nozzle is directed onto the objective 30, through which it is sprayed on with high pressure if necessary. At the front between the fork ends 11, the milling unit 4 sits with the milling cutter 5, where it can be pivoted by means of the worm drive described, as indicated by the arrows. So that the video camera 7 itself can also be pivoted remotely, it can also be built directly on the working head 2. It can then be positioned better for a closer look at the inner tube walls, in particular the inner tube walls of confluent tubes.

The milling unit 4 is shown in FIG. 4 in a cross section. It consists of a housing 18 in which the actual milling head 17 is accommodated in a translationally displaceable manner. The milling cutter 5 is driven pneumatically via a turbine 40. A hollow shaft 6 runs axially along the milling cutter axis, through which cooling water can be pumped, which can cool the actual milling cutter 5 from the inside and then emerges laterally. The displacement of the cutter head 17 in the housing 18th takes place pneumatically in both directions. The milling head 17 is held in a desired extended position according to the invention by means of pneumatically operated oil brake cylinders. The oil circuit, which supplies the said oil brake cylinders with hydraulic oil, is closed within the milling unit 4. In this way it becomes possible, despite the fact that the milling unit 4 is only supplied with air, to generate a very high braking force, so that the milling head 17 extended in the housing 18 can absorb large reaction forces during milling.

FIG. 5 shows the milling unit 4 sitting between the fork ends 11 of the fork 10 in a view from the front, the fork 10 being here in the extended position. As can be seen in this figure, the fork 10 is rounded on its outer sides, so that when the plate disk 9 is rotated in a narrow tube, the fork 10 cannot get stuck with one edge anywhere. The worm drive for pivoting the working head 2, here the milling unit 4, can also be seen. This includes the worm 41 driven from the robot housing and the gearwheel 39, which is firmly connected to the pivot axis of the housing 18. According to the invention, the milling head 17 is mounted inside the housing 18 by means of two opposing sliding shafts made of hardened round steels. Two hardened, parallel arranged round steels 19 are fastened to the milling head 17 on two opposite sides of the milling head 17. On the opposite inner sides of the housing 18 there is a single arranged hardened round steel 20, which lies in the middle between the adjacent round steel pairs 19 on the milling head 17 along one line each. The play of the slide bearing formed in this way can be set by means of the screws 22 on the housing 18, which act on the round steels 20 and thus determine their contact pressure. In addition to the pneumatic cylinder 42, the oil brake cylinder 43 can be seen. If a pressing shoe is built onto the milling head 17, the epoxy resin line is connected to point 48 in FIG. 6.

The working head can also be a separate blowing unit without a milling device, which has a compressed air nipple for attaching the inflation hose of a pig, which is equipped with a one-way valve. With the robot 1, the pig is placed in the conduit or in an opening to be closed and then inflated by means of compressed air, so that it braces in the inner tube in question. The side niches can then be pressed around the entire pig with epoxy resin. The working head can also be a centrifugal unit, which essentially has a pneumatically operated centrifugal disc, onto which a coating material or a paint coat in liquid form can be sprayed from the nozzle on the centrifugal disc on the working head. By means of such a centrifugal unit, inner coatings can be applied to line pipes, which are characterized by a very homogeneous distribution of the coating material. The control valve unit 14 contains the electrically operated pneumatic valves for controlling the robot 1. All the drives of the robot 1 are pneumatic or pneumatic-mechanical, on the one hand, the plate disk 9 is rotated via a toothed wheel gear, which in turn is driven by an air motor, then the working head 2 or the milling unit 4 is pivoted by means of the mechanical worm gear, the worm in turn being driven by an air motor. Furthermore, the milling head 17 is pneumatically retracted and extended and held in any extension position by means of pneumatically operated oil brake cylinders. Finally, the actual milling drive is also pneumatic, in that a turbine 40 inside the milling unit 4 is supplied with compressed air. This drive allows cutter speeds of around 45,000 rpm and correspondingly high milling performance. All of these functions are controlled via the electrically controllable air valves in the control valve unit 14. The spiral mixer is attached below the control valve unit 14. The robot unit 36 advantageously contains in its interior a cross profile running along its longitudinal axis, so that four cross-sectionally V-shaped recesses are formed. The first air motor is accommodated in a first recess, the supply lines for the compressed air and the electrical control lines in a second and fourth recess. The second air motor for the drives is accommodated in a third recess. The individual movements of the robot 1 and the machining operations carried out by it can be carried out continuously monitored by the video camera 8 sitting between the fork 10 and controlled from the above-mentioned supply and control unit, which is equipped with a corresponding monitor, on the basis of the camera image. The control unit even allows the automatic milling of programmable milling curves, which is particularly advantageous for milling out side openings that open. If such a lateral junction is to be newly created or a closed junction is to be reopened, then the pipe wall of the conduit in which the robot 1 is located must be milled out as precisely as possible along the inner contour of the junctioning pipe. The first thing to do is locate the area to be milled. In cases where a previously closed point is to be opened again, this can be done optically by moving the suspected area of the junction and viewing it with the video camera. The previously closed point is usually visually recognizable. In those cases where this point cannot be found optically or in all those cases where a pipe is to open again, an ultrasonic sensor is used, which is mounted on the milling head. The reflected ultrasound signals are different when they hit a pipe wall behind which there is a cavity, for example the interior of a pipe that opens. If this point is found roughly, it is drilled with the milling cutter 5 under video surveillance. Then the milling cutter 5 is moved from the drilled hole over two intersecting directions up to the respective stop. The milling paths can be adjusted via potentiometers be recorded. The control unit is equipped with electronics which, on the basis of the milling paths covered and recorded by the potentiometers in the form of electrical signals, make it possible to calculate the center and the dimension of the merging pipe and to save them as data material. On the basis of this data, the electronics can calculate a round milling curve and then electronically control the milling cutter in such a way that it precisely follows the calculated milling curve, as a result of which the said point is opened cleanly.

The pressing of epoxy resin for the purpose of repairing or closing a line pipe location is carried out after the completion of the milling work or after the insertion of a pig, a pressing unit 23, which can be installed as a separate component instead of the milling unit between the fork ends 11. Advantageously, however, the pressing unit 23 is designed as an attachment, which can be placed directly on the milling head 17 and fastened there by means of screws, as can be seen from FIG. 6. The pressing unit 23 consists of a shoe 24, the shape of which forms a cutout from a hollow cylinder. Skids 25 are mounted on the rounded longitudinal edges of the pressing shoe 24. During processing, these runners 25 rest on the intact line pipe wall on both sides of the point to be processed and thus act as a spacer. The rear end edge of the pressing shoe 24 is designed as a special smoothing edge 26 which acts as a smoothing spatula. Approximately in the middle of the pressing shoe 24 is the outlet Opening 48 for the epoxy resin to be pressed. On the rear side of the pressing shoe 24, a nipple is arranged around the outlet opening, on which the hose for the epoxy resin is mounted. In use, the pressing shoe 24 is moved under video surveillance to the point to be repaired or closed and then pressed onto this point by extending the milling head 17. The lateral runners 25 rest on an intact area around the point to be pressed and define the position of the pressing shoe 24. Now the supply unit pre-presses the two components of the epoxy resin from the supply unit, which are directly in front of the Use and processed virtually on site in a spiral mixer 46, as will be described. If it is determined by the video surveillance that the injected epoxy resin has filled the site sufficiently, the pressing shoe 24 is pivoted about its radius of curvature along its runners 25 by pivoting the milling unit 4 or by rotating the fork 10 by means of the plate disk 9. The smoothing edge 26 brushes precisely at the level of the runners 25 and thus at the level of the surrounding inner wall area over the point pressed with epoxy resin and smooths the epoxy resin cleanly.

FIG. 7 shows a counter-rotating spiral mixer in a side view with the wall partially cut open. It is a plastic tube 46 with a slightly tapering diameter towards the front. Inside the art Fabric tube 46 is arranged a row of rectangles 47 each twisted by 180 °, so that their longitudinal edges each form a helical shape. The individual twisted rectangles 47 or twisting elements 47 are lined up in such a way that the straight end edges or broad sides of the twisted rectangles 47 adjoin one another at right angles to one another. The two components of the epoxy resin pressed by this spiral mixer are rotated by 180 ° by each twisting element 47 and then each component is divided in two by the front edge of the next twisting element 46 and brought together with half of the other component. In each twist element 47 two new parts arriving separately from the preceding twist element 47 are therefore mixed together on both sides of the surface. This process extends over approximately 10 torsion elements 47, as a result of which a very intimate mixing of the two original components is achieved. This spiral mixer 46 is accommodated below the valve control unit 14. From there, the finished epoxy resin mixture thus emerges from the supply line 35 and reaches the pressing unit 23, by means of which the epoxy resin is applied to the point in the conduit to be repaired or sealed.

In Figure 8, the execution of the synchronous drive of the locomotive 8 is shown. Between the front and rear drive wheels 12, each of which is connected to one another via a rigid axle, there is a series of gear teeth of the same size. wheels 29 odd number arranged, which transmit the driving force from the drive axle 44 to the other 45. This type of power transmission ensures absolutely synchronous running of the four drive wheels 12 of the locomotive 8 without play and with the smallest space requirement and most effective power transmission. These gear wheels 29 are each arranged on a separate plate 38, which in turn is screwed tightly to the housing 27. The entire, gas-tight housing of the locomotive 8 is filled with nitrogen under an overpressure of approximately 0.2 bar with respect to the environment in order to prevent any ingress of moisture or water. This overpressure can be checked regularly and, if necessary, supplemented via a valve provided on the locomotive housing 27. The electric motor in the interior of the locomotive housing has, for example, a nominal motor voltage of 60 V at 5 A current. It is equipped with a tachometer generator which is coupled to a transformer and amplifier in the supply and control unit. A voltage drop due to a drop in the speed of the electric motor is automatically compensated by the supply and control unit by means of the transformer and the amplifier with a higher current intensity in accordance with an optimized characteristic characteristic of the motor. The four specially developed solid rubber studded tires 28, which are provided with many rubber studs all around the visible tire cross-section, ensure optimal power transmission of the locomotive 8 in order to achieve the highest possible adhesion to the curved inner wall of the conduits used. So that the device can also be used in conduits with considerably larger diameters than in those whose inner wall can be reached by the robot lying on the conduit floor, the robot 1 can be equipped in two places with chassis legs which can be extended by it instead of runners . These chassis legs can be extended pneumatically, for example, and held in any extended position by means of pneumatically operated oil brake cylinders. The undercarriage legs are advantageously equipped with freewheeling wheels in such a way that the robot 1 can be stabilized about its longitudinal axis in the center in the center for processing in large-diameter pipes and still remains displaceable by the locomotive 8.

Claims

^• Claims

Process for the internal processing of non-accessible line pipes, in which a remote-controlled robot (1) with video-monitored working head (2), which is inserted into the pipe to be processed from a supply and control unit arranged above ground, the location to be opened or repaired milled out, or placed a pig at the point to be closed and braced by inflation in the conduit, characterized in that a) if it was milled out, it was operated with a pneumatically driven milling cutter (5) at a speed of more than 35,000 U / min takes place; b) for the repair, two components of a two-component epoxy resin are pressed from the supply and control unit to the robot (1) via two separate hose lines (35); c) the two components are mixed in a spiral mixer (46) immediately before reaching the working head (2) to form an intimate, hardening epoxy resin mixture; d) the milled point or the area in front of the braced pig is pressed and smoothed with the mixed, hardening epoxy resin. Method according to Claim 1, in which the location to be opened is milled out by a) moving the location to be opened via the video camera (7) or by means of ultrasound sensors, b) drilling the location to be opened , c) from the bore one after the other in two intersecting directions back and forth up to the stop, the milling paths being measured electronically and the center and the dimension of the merging pipe and the associated milling curve being calculated and stored therefrom d) the electronically stored milling curve is traversed, whereby the location is opened as desired.

Device for carrying out the method according to claim 1 or 2, with a remote-controlled robot (1) which can be moved into the conduit to be processed, with a video-monitored working head (2) and an associated supply and control unit arranged above ground, da¬ characterized in that at the front of the robot (1) there is a dial plate (9) which can be rotated more than 360 ° about its longitudinal axis and which carries a fork (10) provided with a joint (13), between the fork ends ( 11) a working head (2) can be swiveled and extended which is stored as a milling unit (4) for milling out spots, as a blowing unit for bracing pigs, as a pressing unit (23) for pressing and smoothing epoxy resin, as a centrifugal unit for coating pipes internally, or as a combination of such units (4; 23 ) is trained.

Device according to claim 3, characterized in that the robot (1) is an element of a train composition comprising a locomotive (8), valve control unit (14) and robot (1), these three elements (1, 8, 14) above all ¬ joints (15, 16) which can be pivoted but cannot be rotated relative to one another are connected in such a way that the robot (1) is held against rotation in the interior of the tube without any additional tensioning means, and that electronic measuring devices are provided by means of which all movements are carried out the train composition, namely horizontal travel of the locomotive (8), rotation of the fork (10) and the pivoting and extending of the working head (2) can be detected and controlled.

Device according to one of claims 3 or 4, characterized in that the working head (2) has a blowing and milling unit (4) with a pneumatically extendable milling head (17) which is fixed in each extended position by means of pneumatically operated, hydraulic oil brake cylinders. is adjustable, the oil circuit inside the milling unit (4) is closed.

Device according to one of claims 3 to 5, characterized in that the blowing and milling unit (4) has a housing (18) in which the milling head (17) can be extended with sliding bearings, the sliding bearings on two sides of the milling head (17) are formed on the one hand by two hardened round steels (19) arranged in parallel on the milling head (17), and on the other hand in each case by one hardened round steel (20) on the opposite inner sides of the housing (18) such that the individual round steels (20) in the middle between the round steel pairs (19) lie on each of these along a line, the play of these slide bearings being adjustable by adjusting the contact pressure by means of screws (22) on the housing (18) which hold the hardened round steel ( 20) on the housing (18).

7. Device according to one of claims 3 to 6, characterized in that the working head (2) can be pneumatically mechanically brought into its pivoting position by means of a worm drive and can be ascertained there due to the self-locking of the worm drive, and that during the formation of the working head (2) as a blowing and milling unit (4) of the milling cutter (5) pneumatically via a door bine (40) is drivable, a hollow shaft (6) being provided, via which the milling cutter (5) can be water-cooled from the inside, in that water can be conducted from the inside of the milling cutter (5) to the outside.

Device according to one of claims 3 to 7, characterized in that the working head (2) is designed as a pressing unit (23), a counter-rotating spiral mixer (46) being accommodated in front of the working head (2) in the valve control unit (14), by means of which the epoxy resin components can be intimately mixed immediately before being pressed into the working head (2), and that the pressing unit (23) has a rounded pressing shoe (24) with runners (25) on both sides and a smoothing edge (26) of which the mixed epoxy resin mixture can be pressed onto the area to be machined and smoothed there.

Device according to one of claims 3 to 8, characterized in that the locomotive (8) has a one-piece housing (27) which is sealed gas-tight under N ₂ ~ overpressure and of four wheels (12) fitted with studded tires (28). is driven, which are driven collectively via a series of gear wheels (29) synchronously by a single electric motor, which is equipped with a tachometer generator, such that a Voltage drop due to the drop in speed of the electric motor is automatically compensated for by the supply and control unit by means of a transformer and amplifier with a higher current intensity in accordance with an optimized characteristic curve typical of the motor.

10. Device according to one of claims 3 to 9, characterized in that the video camera (7) is arranged directly on the working head (2) and its lens (30) is directed at an angle of approximately 45 ° to the milling cutter axis on the machining point.

11. Device according to one of claims 3 to 10, characterized in that the pressing unit (23) can be mounted directly on the milling head (17).

12. The device according to one of claims 3 to 11, characterized in that the robot (1) is equipped at two locations with star-shaped extendable, pneumatically actuated ren and lockable by means of pneumatically operated oil brake cylinders with free-wheeling wheels, such that it can be stabilized around its longitudinal axis for processing in large-diameter pipes in the center thereof. 13. Device according to one of claims 3 to 12, characterized in that a centrifugal unit is inserted between the fork ends (11), by means of which the inner surface of the pipe to be processed can be coated.