A method for cleaning the interior of pipes using a cleaning device and a cleaning device. The cleaning device has a tube and an advancing unit for moving the tube along a main axis (H) of the advancing unit. The advancing unit has a drive which is frictionally connected to the tube and by which the tube is moved in an axial direction along the main axis (H). The advancing unit is set into a rotational movement about the main axis (H) during the axial movement of the tube, and the drive transmits the rotational movement to the tube.

A method for cleaning the interior of pipes using a cleaning device and a cleaning device. The cleaning device has a tube and an advancing unit for moving the tube along a main axis (H) of the advancing unit. The advancing unit has a drive which is frictionally connected to the tube and by which the tube is moved in an axial direction along the main axis (H). The advancing unit is set into a rotational movement about the main axis (H) during the axial movement of the tube, and the drive transmits the rotational movement to the tube.

A procedure for cleaning a pipe or shaft with a cleaning nozzle operated with a cleaning liquid and having a camera module includes the following steps: recording a video during or after the cleaning; transmitting the video to a mobile device over a first distance; transmitting the video with collected corresponding position data of the cleaning location of the pipe or of the shaft to a memory, which is protected by a cleaning service provider and/or nozzle manufacturer, in a data cloud over a second distance; and making the protected memory in the data cloud of the cleaning service provider and/or nozzle manufacturer accessible by the customer commissioning the cleaning procedure. The recorded videos with stored road map are displayed on a screen, and each video with corresponding cleaning location can be accessed from the memory in the data cloud.

The present invention provides a pulling system essentially consisting of two sets of feet (11) and a hydraulic cylinder (15). Each set is positioned on one of the sides of the hydraulic cylinder (15). The two sets of feet (11) have a self-locking mechanism. The self-locking mechanism allows each set of feet to act preferentially on one side and exert powerful forces. The invention further provides a flexible reservoir (21) capable of equalizing the pressures inside and outside the medium, allowing the operation of a hydraulic system in an environment that is subjected to any pressure value, provided that it is within the operating range of the components. In addition, the maintenance of a closed circuit ensures that no fluid contamination occurs.

The present invention provides a pulling system essentially consisting of two sets of feet (11) and a hydraulic cylinder (15). Each set is positioned on one of the sides of the hydraulic cylinder (15). The two sets of feet (11) have a self-locking mechanism. The self-locking mechanism allows each set of feet to act preferentially on one side and exert powerful forces. The invention further provides a flexible reservoir (21) capable of equalizing the pressures inside and outside the medium, allowing the operation of a hydraulic system in an environment that is subjected to any pressure value, provided that it is within the operating range of the components. In addition, the maintenance of a closed circuit ensures that no fluid contamination occurs.

A system includes an inspection robot for performing an inspection on an inspection surface with ultrasonic and magnetic induction sensors, the apparatus comprising a position definition circuit structured to determine an inspection robot position on the inspection surface; a data positioning circuit structured to interpret inspection data, and to correlate the inspection data to the inspection robot position on the inspection surface; and wherein the data positioning circuit is further structured to determine position informed inspection data in response to the correlating of the inspection data with the inspection robot position.

The invention relates to an apparatus and method for scarifying the interior surface of pipes, such as a sewer pipe. The apparatus comprises a chassis, a carriage coupled to the chassis to reciprocate along a longitudinal axis of the chassis, a shaft capable of indexing rotation coupled to the carriage, and arms extending radially from the indexing shaft and tipped in high-pressure nozzle assemblies. The method comprises positioning the apparatus in a pipe and alternately reciprocating the carriage and indexing the shaft so as to scarify to successive longitudinal swathes of the pipe surface until the desired circumference of the pipe section is scarified. The apparatus is then repositioned in the next section of pipe and the method is repeated until the desired length of pipe is scarified. The invention may further comprise a separable propulsion unit.

The invention relates to an apparatus and method for scarifying the interior surface of pipes, such as a sewer pipe. The apparatus comprises a chassis, a carriage coupled to the chassis to reciprocate along a longitudinal axis of the chassis, a shaft capable of indexing rotation coupled to the carriage, and arms extending radially from the indexing shaft and tipped in high-pressure nozzle assemblies. The method comprises positioning the apparatus in a pipe and alternately reciprocating the carriage and indexing the shaft so as to scarify to successive longitudinal swathes of the pipe surface until the desired circumference of the pipe section is scarified. The apparatus is then repositioned in the next section of pipe and the method is repeated until the desired length of pipe is scarified. The invention may further comprise a separable propulsion unit.

Transit Cleaning Unit is able to clean the walls, overhead, insulators third rail covers and flooring of the subway systems in a minimum amount of time.

It provides an effective means of providing a clean environment for the benefit of the customers.

A nozzle assembly includes a stator including a front portion optionally with a first nozzle configured to direct an optional first stream of a cleaning fluid in a forward direction of the nozzle assembly, a rear portion including a second nozzle configured to direct a second stream of the cleaning fluid rearward of the nozzle assembly, a rotor disposed between the front portion and the rear portion along a longitudinal axis of the nozzle assembly and including a third nozzle configured to direct a third stream of the cleaning fluid; and a magnetic brake disposed between the stator and rotor.