Patent Application
20180056342
The present invention relates to a cleaning device, and particularly to a cleaning device for removing material inside a pipe.
Installed pipelines in buildings and underground can be rehabilitated without opening structures or digging the ground. The trenchless rehabilitation allows a quick and durable rehabilitation of pipes within buildings and underground pipelines. An old pipe is first cleaned thoroughly by removing any residues, rust and roots that have penetrated into the pipe. A resin impregnated liner is installed in the cleaned pipe with an inversion drum using air pressure to invert the liner into the pipe. Once the liner is installed air pressure is maintained on an elevated level until the resin within the liner settles and the liner forms a rigid pipe against the inner surface of the old pipe. A drop in air pressure inside the pipe during a settling period may cause collapse of the liner which blocks or at least severely restricts the flow of fluids in the pipe. Once the collapsed liner has settled inside the pipe it can only be removed by mechanically sanding or grinding the collapsed liner into small fragments which can then be removed from the pipe.
One of the problems associated with the above arrangement is that initial cleaning of the pipe is difficult if the pipe has cracks or holes into which cleaning tools get stuck. Another problem is that removing a collapsed liner needs special tools and it is tedious and hard work which may take several weeks to finish for a long pipe and it causes significant delays and additional expenses to a rehabilitation project.
An object of the present invention is to provide a cleaning device which significantly speeds up the removal of a collapsed liner and other blockages from a pipe. Another object of the present invention is to provide a cleaning device which can be used also in damaged pipes.
The present invention is based on the idea of providing pivotally connected cutters on a body that can be rotated so that the cutters open towards inner wall of a pipe and the device automatically adapts to various diameters of the pipe.
An advantage of the arrangement of the present invention is that the device rigid but pivotally connected cutters so the device adjusts to changes in diameter and other irregularities inside a pipe. Long and curved shape of the cutters and relatively high rotating mass of the device makes it efficient in cleaning and insensitive to cracks and holes in the pipe.
In the following the present invention is described in greater detail by means of preferred embodiments with reference to the accompanying drawings, in which
The cleaning device comprises a body having a front body member 30 and a back body member 50 that has a connector 53, 54 for a drive shaft. The front body member 30 has apertures 31 or recesses defined therein and the back body member 50 has apertures 51 or recesses defined therein. Pins 16 are accommodated in said apertures or recesses of the front body member and back body member. The pins 16 extend between the front body member and back body member. The pins have preferably a circular cross-section. The body is preferably made of a metal, such as aluminum, iron or steel. The body may comprise multiple parts fixed together e.g. with screws and/or bolts and nuts. The connector 53, 54 is preferably a socket 53 that has a slightly larger diameter than the drive shaft. Preferably, two or more threaded apertures 54 are provided on the side of the socket for accommodating tightening screws. Also a quick lock connector can be used. The connector is provided on a reverse side of the back body member of the cleaning device so that the cleaning device can be pushed forward in a pipe by pushing the drive shaft into the pipe. An end of the drive shaft is inserted into the socket and the drive shaft is secured to the connector by tightening the tightening screws against the drive shaft. The drive shaft is preferably made of a steel cable or similar flexible drive shaft that has some flexibility to be able to bend through bends of a pipeline.
Once the drive shaft is secured to the connector 53, 54, the cleaning device can be operated by rotating the drive shaft. The rotation of the drive shaft rotates the body of the cleaning device around a rotation axis RA illustrated in
The cleaning device comprises a first set of grinding cutters 11 pivotally attached to the pins 16 of the body. The cutters have an aperture defined therein and extending through the cutters for accommodating the pins 16 for allowing pivotal movement of the cutters. The pivotal connection allows movement of a cutter in a plane perpendicular to the rotation axis RA. The cutters can therefore turn to increase or decrease diameter of the cleaning device. The cutters have cutting edges on their long outer surface from the rotation axis RA. Said cutting edges are preferable parallel to the rotation axis to prevent causing a pushing force or a pulling force on the device while rotating. In an embodiment said cutting edges are not parallel to the rotation axis in order to exert a pushing force or a pulling force on the device while rotating. Said cutting edges are provided on the cutter surface by cutting oval arcs, circular arcs, quadratic notches or other recesses on the surface of the cutter. Also pieces of metal, preferably hard metal, can be fixed to the cutter for providing cutting edges. The cutters have preferably a curved shaped and the cutting edges are provided on a convex surface whereas the opposing concave surface faces towards the body of the cleaning device. The curved shape of the cutters better adaptation to changing diameter of a pipe and also divides the cleaning action to a larger number of cutting edges.
Cutting edges can be provided in various angles in relation to radial direction from the rotation axis. This angle defines how aggressively the cutting edges cut the material they hit onto in the pipe. The radial direction would be 0° in which the cutting edge points in a direction straight out from the rotation axis.
A leading cutting edge is inclined towards the direction of rotation and it tends to dig into the material. The leading cutting edge is aggressive and effective and therefore suitable for removing hard materials. The leading cutting edge may cut too deep and get jammed or stuck in to the material if it's soft and/or resilient as the leading edge design cuts into the material. A trailing cutting edge on the other hand is inclined away from the direction of rotation. It could be described as sweeping the surface instead of cutting into it. The trailing cutting edge is suitable for removing softer materials and for performing general cleaning of small residues. A cutter having the trailing cutting edges is safe to use because there is no risk of jamming.
The cutters clean and remove material inside a pipe from sides of the cleaning device as the cutting edges are on the perimeter of the cleaning device. The cutters turn away from the body when the body is rotated and diameter of the cleaning device increases until the cutters face an obstacle or the inner surface of the pipe. At that point cutting edges come into contact with the obstacle or the inner surface of the pipe and scrape or grind the obstacle and/or surface thereby cleaning the pipe. When the rotation is stopped, decelerating rotary motion turns the cutters against the body and this way the cleaning device can be fitted though smaller holes or into smaller cavities.
In an embodiment the cleaning device comprises a second set of cutters 12 and a spacer 40 provided between cutters of the first set of cutters and the second set of cutters. The spacer is preferably disc-shaped and the spacer 40 has apertures defined therein for accommodating the pins 16. The spacer defines a gap between the first set of cutters 11 and the second set of cutters 12 thereby allowing cutters to move individually and preventing the cutters of the first set of cutters and the cutters of the second set of cutters from hitting each other. The second set of cutters stabilizes the cleaning device and helps in maintaining the rotation axis of the cleaning device in same direction as the pipe. The second set of cutters also increases the surface area that is being cleaned at a time.
In an embodiment the second set of cutters 12 consists of larger or smaller cutters than the first set of cutters 11. Smaller cutters near the front body member facilitate entering into a smaller cavity and the smaller cutters can enlarge the cavity so that the larger cutters near the back body member can enter the cavity and remove and remaining material in that particular section of the pipe. In an embodiment the cleaning device comprises multiple sets of cutters having spacers provided between each set of cutters. The size of the cutters between the sets of cutters remains the same or increases between each subsequent set of cutters in a direction from the front body member towards the back body member. This way entering into small cavities is facilitated and/or the surface area that is being cleaned at a time increases.
In an embodiment, the cleaning device has apertures 31 defined in the front body member 30 extending through the front body member 30 thereby allowing removal of the pins 16 and the cutters 11. The cleaning device further comprises a removable front plate 20 attached to the front body member 30, e.g. with screws or bolts. The front plate at least partially covering said apertures 31 for securing the pins 16. The cutters can be changed by removing the front plate 20 and removing the pins 16 and thereby releasing the cutters. New cutters can be placed in and the pins are inserted through the apertures of the front body member and through the apertures of the cutters into the apertures or recesses of the back body member and then attaching the front plate back onto the front body member for locking the pins in again.
In an embodiment the front plate 20 can be substituted with a cutting panel, grinding panel or sanding panel for removing material from a pipe when the cleaning device is pushed forward in the pipe. Said panel preferably removes material and defines a cavity in which the first set of cutters can be inserted for widening the cavity with the cutters and ultimately cleaning the pipe. Said panel can also be attached to the tool in addition to the front panel 20.
In an embodiment, the cleaning device comprises a centering device for centering the cleaning device within a pipe. In an embodiment, a set of cutters 11, 12 can be a centering device. In an embodiment the centering device comprises a body having stiff brushes radially extending from the body for centering the cleaning device within the pipe. The body of the centering device preferably surrounds the body of the cleaning device or the shaft. The body of the centering device preferably comprises bearings for eliminating or decreasing transmission of rotary motion of the shaft or the body of the cleaning device to the centering device to prevent wearing of the brushes. The brushes point radially out from the body of the centering device and the brushes are preferably configured to reach the inner surface of the pipe around the pipe. Thus the diameter of the centering device is equal or close to equal to the diameter of the pipe. The centering device can be located along the rotational axis of the cleaning device in front and/or behind the front body member and/or back body member. In an embodiment the centering device is located along the rotational axis of the cleaning device on both sides of a set of cutters.
It will be obvious to a person skilled in the art that, as the technology advances, that the inventive concept can be implemented in various ways. The present invention and its embodiments are not limited to the examples described above but may vary within the scope of the claims.
| Number | Date | Country | Kind |
|---|---|---|---|
| 20165641 | Aug 2016 | FI | national |
