EP1960763A1 - Appareil et procede servant a effectuer une inspection video a distance depuis le haut - Google Patents

Appareil et procede servant a effectuer une inspection video a distance depuis le haut

Info

Publication number
EP1960763A1
EP1960763A1 EP06804735A EP06804735A EP1960763A1 EP 1960763 A1 EP1960763 A1 EP 1960763A1 EP 06804735 A EP06804735 A EP 06804735A EP 06804735 A EP06804735 A EP 06804735A EP 1960763 A1 EP1960763 A1 EP 1960763A1
Authority
EP
European Patent Office
Prior art keywords
mast
imaging system
camera
inspection
extending portion
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP06804735A
Other languages
German (de)
English (en)
Other versions
EP1960763A4 (fr
Inventor
Alain Lortie
Sébastien BLIER
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
CT-Zoom Technologies Inc
Original Assignee
CT-Zoom Technologies Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from US11/274,316 external-priority patent/US20070109416A1/en
Priority claimed from US11/280,201 external-priority patent/US8525877B2/en
Priority claimed from US11/280,202 external-priority patent/US8773525B2/en
Application filed by CT-Zoom Technologies Inc filed Critical CT-Zoom Technologies Inc
Priority to EP10185956A priority Critical patent/EP2288160A3/fr
Publication of EP1960763A1 publication Critical patent/EP1960763A1/fr
Publication of EP1960763A4 publication Critical patent/EP1960763A4/fr
Withdrawn legal-status Critical Current

Links

Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04NPICTORIAL COMMUNICATION, e.g. TELEVISION
    • H04N7/00Television systems
    • H04N7/18Closed-circuit television [CCTV] systems, i.e. systems in which the video signal is not broadcast
    • H04N7/183Closed-circuit television [CCTV] systems, i.e. systems in which the video signal is not broadcast for receiving images from a single remote source
    • EFIXED CONSTRUCTIONS
    • E03WATER SUPPLY; SEWERAGE
    • E03FSEWERS; CESSPOOLS
    • E03F7/00Other installations or implements for operating sewer systems, e.g. for preventing or indicating stoppage; Emptying cesspools
    • E03F7/12Installations enabling inspection personnel to drive along sewer canals
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N21/00Investigating or analysing materials by the use of optical means, i.e. using sub-millimetre waves, infrared, visible or ultraviolet light
    • G01N21/84Systems specially adapted for particular applications
    • G01N21/88Investigating the presence of flaws or contamination
    • G01N21/95Investigating the presence of flaws or contamination characterised by the material or shape of the object to be examined
    • G01N21/954Inspecting the inner surface of hollow bodies, e.g. bores

Definitions

  • TITLE APPARATUS AND METHOD FOR CONDUCTING REMOTE VIDEO INSPECTION FROM ABOVE
  • the present invention generally relates to the remote inspection of areas that are difficult to reach. More specifically, the invention relates to inspection of underground sewers, railroad bridge support structures and other facilities that may be examined remotely from a location above, using a video camera or other imaging system.
  • Known vehicle mounted inspection cameras have a major drawback however. Since the camera and mast are lowered vertically from the vehicle, they are not capable of adequately reaching lateral sewer pipes that are offset from the manhole. Although most manholes are positioned squarely above the lateral conduits that they access, some manholes are substantially offset, generally because of an obstacle being in the way. In many municipalities, approximately 10 % of the underground piping network does not receive proper routine inspection with known equipment because the pipes are offset from the manholes that access them.
  • imaging systems used for inspection of underground conduits should be specially accommodated to operate efficiently in gloomy, humid and difficult to reach areas in order to be able to provide quality of imaging in a cost effective and a non time-consuming way.
  • Traditional imaging systems for inspection of underground conduits lack efficiency because they are not suitably accommodated for such inconvenient areas.
  • an apparatus for conducting remote subsurface inspection from above comprises a support structure, a mast, an imaging system and an offsetting mechanism.
  • the support structure has an articulating radial arm and is adapted to be positioned above a working surface.
  • the articulated radial arm has a pivot at one end and a coupling at the other end.
  • the pivot has a rotation axis substantially normal to the working surface.
  • the support structure further comprises a retractable ground contacting leg to aid in stabilizing the mast when the apparatus is in use.
  • the mast is held by the coupling and is born generally upright in use by the support structure.
  • the mast has a portion that is downwardly extendable below the working surface and has a mounting on that extending portion to hold an imaging system.
  • An actuating mechanism is preferably used to extend and retract the extending portion of the mast.
  • the mast comprises telescoping cylindrical sections.
  • the imaging system comprises a video camera having a zoom lens of at least 20 times magnification.
  • the imaging system preferably further comprises at least one light. More preferably, a plurality of lights is arranged around the video camera.
  • the offsetting mechanism is operative to displace the imaging system laterally from a vertical reference axis beneath the coupling when the extending portion of the mast has been extended below the working surface.
  • the coupling preferably comprises a mast pivot having a mast rotation axis substantially perpendicular to the extension axis of the mast.
  • the mast is maneuverable to allow its rotation with respect to the support structure around the mast rotation axis.
  • the mounting comprises an adjustable interconnection between the imaging system and the extending portion of the mast.
  • the interconnection is remotely maneuverable from a first position in which the imaging system is proximal to the extending portion of the mast, to a second position in which the imaging system is displaced from the extending portion of the mast.
  • the articulating radial arm comprises a plurality of sections joined by swivels. More preferably, the swivels and the mast pivot have locking mechanism to prevent their free rotation. Even more preferably, the support structure comprises an adaptor section adapted to fit to a hitch installed on a vehicle.
  • a display may optionally be provided to display images from the imaging system.
  • the display is mounted on a portion of the mast that is not downwardly extendable below the working surface.
  • a method for conducting remote subsurface inspections from above comprises the steps of (a) locating an access point on a working surface above a subsurface area, (b) positioning an apparatus for conducting remote subsurface inspections from above as disclosed here above disclosed proximal to the access point, (c) manipulating the mast of the apparatus in vertical alignment with the access point, (d) lowering the extending portion of the mast downwardly into such subsurface area until the imaging system of the apparatus is at the level to be inspected and (e) reviewing images of such subsurface area from the imaging system.
  • the mast is lowered vertically, or substantially vertically, in the subsurface area.
  • the method further comprises the step of displacing the imaging system laterally from a vertical reference axis beneath the coupling of the support structure of the apparatus when the extending portion of the mast has been extended below the working surface.
  • the coupling comprises a mast pivot
  • the step of displacing the imaging system laterally comprises maneuvering the mast pivot to rotate the mast with respect to the support structure.
  • the mounting of the extending portion of the mast comprises an adjustable interconnection between the imaging system and the extending portion of the mast.
  • the step of displacing the imaging system laterally comprises remotely maneuvering the adjustable interconnection from a first position in which the imaging system is proximal to the extending portion of the mast, to a second position in which the imaging system is displaced from the extending portion of the mast.
  • an apparatus for conducting remote subsurface inspections from above which comprises a support structure, a mast and an imaging system.
  • the support structure has an articulated radial arm and a coupling and is adapted to be positioned above a working surface.
  • the articulated radial arm is connected to the coupling.
  • the mast is held by the coupling and is born generally upright in use by the support structure.
  • the mast comprises telescoping cylindrical sections.
  • the mast has an extending portion that is downwardly extendable below the working surface.
  • the extending portion has a mounting thereon.
  • the imaging system is held by the mounting on the extending portion of the mast.
  • the imaging system comprises a video camera.
  • the apparatus preferably comprises an offsetting mechanism that is operative to displace the imaging system laterally from a vertical reference axis beneath the coupling when the extending portion of the mast has been extended below the working surface.
  • the coupling comprises a mast pivot having a mast rotation axis that is substantially perpendicular to the extension axis of the mast. The mast pivot is maneuverable to allow rotation of the mast with respect to the support structure around the mast rotation axis.
  • the mounting comprises an adjustable interconnection between the imaging system and the extending portion of the mast.
  • the interconnection is remotely maneuverable from a first position in which the imaging system is proximal to the extending portion of the mast, to a second position in which the imaging system is displaced from the extending portion of the mast.
  • the articulating radial arm comprises a plurality of sections joined by swivels. More preferably, the support structure further comprises a retractable ground contacting leg to aid in stabilizing the mast when the apparatus is in use. Even more preferably, the support structure comprises an adaptor section adapted to fit to a hitch installed on a vehicle.
  • an apparatus for conducting remote subsurface inspections from above comprises a support structure, a mast and an imaging system.
  • the support structure has a coupling and has a fitting to secure the apparatus to a hitch receiver installed on a vehicle.
  • the support structure is positioned above a working surface.
  • a mast is held by the coupling and is born by the support structure.
  • the mast has an extending portion that is downwardly extendable below the working surface.
  • an actuating mechanism operative to extend and retract the extending portion of the mast is used.
  • the mast comprises telescoping cylindrical sections.
  • the mast also has a mounting thereon.
  • An imaging system is held by the mounting on the extending portion of the mast.
  • the imaging system comprises a video camera. More preferably, the imaging system further comprises a plurality of lights arranged around the video camera. Even more preferably, the video camera comprises a zoom lens of at least 20 times magnification.
  • At least one hitch receiver is installed on a vehicle and the fitting comprises a bar adapted to be removably held within the hitch receiver such that the support structure is oriented to bear the mast generally upright in use. More preferably, the support structure further comprises an articulating radial arm connecting the mast thereto. Even more preferably, at least one hitch receiver is a standard trailer hitch receiver.
  • a plurality of hitch receivers is installed on a vehicle. Preferably, at least one of the hitch receivers is installed at the side of the vehicle.
  • the apparatus advantageously comprises an offsetting mechanism operative to displace the imaging system laterally from a vertical reference axis beneath the coupling when the extending portion of the mast has been extended below the working surface.
  • the coupling preferably comprises a mast pivot having a mast rotation axis substantially perpendicular to the extension axis of the mast.
  • the mast pivot is maneuverable to allow rotation of the mast with respect to the support member around the mast rotation axis.
  • the mounting optionally comprises an adjustable interconnection between the imaging system and the extending portion of the mast, the interconnection being remotely maneuverable from a first position in which the imaging system is proximal to the extending portion of the mast, to a second position in which the imaging system is displaced from the extending portion of the mast.
  • the articulating radial arm comprises a plurality of sections joined by swivels. More preferably, the swivels and the mast pivot have locking mechanism to prevent their free rotation. Even more preferably, the support structure further comprises a retractable ground contacting leg to aid in stabilizing the mast when the apparatus is in use.
  • the apparatus further comprises a display to display images from the imaging system.
  • the display is mounted on a portion of the mast that is not downwardly extendable below the working surface.
  • a method for conducting remote subsurface inspections from above comprises the steps of (a) locating an access point on a working surface above a subsurface area, (b) positioning an apparatus for conducting remote subsurface inspections from above as disclosed here above proximal to the access point.
  • the apparatus further comprises at least one hitch receiver installed on a vehicle, wherein the fitting comprises a bar adapted to be removably held within the hitch receiver such that the support structure is oriented to bear the mast generally upright in use.
  • the support structure comprises an articulating radial arm connecting the mast thereto.
  • the apparatus also comprises an offsetting mechanism operative to displace the imaging system laterally from a vertical reference axis beneath the coupling when the extending portion of the mast has been extended below the working surface, (c) manipulating the mast of the apparatus in vertical alignment with the access point, (d) lowering the extending portion of the mast downwardly into such subsurface area until the imaging system of the apparatus is at the level to be inspected and (e) reviewing images of such subsurface area from the imaging system.
  • the method optionally comprises the step of displacing the imaging system laterally from a vertical reference axis beneath the coupling of the support structure of the apparatus when the extending portion of the mast has been extended below the working surface.
  • the coupling comprises a mast pivot
  • the step of displacing the imaging system laterally comprises maneuvering the mast pivot to rotate the mast with respect to the support structure.
  • the mounting of the extending portion of the mast advantageously comprises an adjustable interconnection between the imaging system and the extending portion of the mast.
  • the step of displacing the imaging system laterally comprises remotely maneuvering the adjustable interconnection from a first position in which the imaging system is proximal to the extending portion of the mast, to a second position in which the imaging system is displaced from the extending portion of the mast.
  • a vehicle hitch mounting structure having a first and a second receivers.
  • the first and second receivers comprise corresponding first and second longitudinal planes and first and second transversal planes.
  • the first longitudinal plane is parallel to the second longitudinal plane and the first transversal plane is substantially perpendicular to the second transversal plane.
  • Both first and second receivers are of the same type.
  • the hitch further includes a third receiver placed co- linearly with the second receiver.
  • the third receiver faces a direction that is opposite to the direction faced by the second receiver.
  • first, second and third receivers are standard trailer hitch receivers.
  • the vehicle hitch mounting structure further comprises a vehicle body.
  • an inspection system that comprises a mast, a support member to support the mast, a camera with a first interface unit to control attributes of the camera.
  • the camera is mounted on the mast.
  • the system also comprises a controllable high magnification ratio zoom with a zoom controller to control the high magnification ratio zoom.
  • the zoom is mounted on the mast electronically controllable light projectors with a second interface unit to control attributes of the light projectors, the light projectors being mounted on the mast; motors with a motor controller to mechanically control orientation of the camera, the zoom and the light projectors with respect to the mast; and a third interface unit located in proximity of the camera, the light projectors and the motors, the third interface unit having a single input signal and output signals connecting the third interface unit to each of the camera, the zoom controller, the light projectors and the motor controller.
  • an inspection system comprising: a mast; a support member to support the mast; a camera having an output video signal, the camera being mounted on the mast; a server connected to the camera to store at least a part of the video signal outputted by the camera; and
  • a method of automatically generating attribute values defining controllable attribute values of an inspection imaging system comprising steps of: manually setting each of the attribute values to put the inspection system in an initial state; selecting a navigation template among stored navigation templates, where the navigation template contains at least one set of the attribute values defining controllable attribute values of an inspection imaging system; executing the navigation template during inspection of the inspecting object to generate the at least one set of the attribute values, the attribute values including camera orientation, camera zoom and lighting intensity; and sending the at least one set of the attribute values to the inspection imaging system to automatically navigate according to the selected navigation template.
  • a system for automatically generating attribute values defining controllable attribute values of an inspection imaging system comprising: a user interface unit receiving user friendly data commands from an end user to define the controllable attribute values; a motor control module connected to the user interface unit to acquire a first user friendly data command and outputting a first attribute signal to control position and orientation of the inspection imaging system; a zoom module connected to the user interface unit to acquire a second user friendly data command and outputting a second attribute signal to control a high magnification ratio zoom of a camera of the inspection imaging system; a camera module connected to the user interface unit to acquire a third user friendly data command and outputting a third attribute signal to control attributes of the camera; a light projector module connected to the user interface unit to acquire a fourth user friendly data command and outputting a fourth attribute signal to control attributes of electronically controllable light projectors of the inspection imaging system; and an interface unit receiving the attribute signals and outputting corresponding imaging system control signals; a storage unit receiving the attribute signals and outputting corresponding imaging system control signals; a storage unit
  • a method of creating an identification header using a database to automatically extract information in connection with an inspecting object comprising steps of: navigating an inspection imaging system mounted on a mast supported by a support member to inspect the inspecting object; recording the inspection to create an inspection video in connection with the inspecting object; selecting the inspecting object in a database containing information about the inspecting object; extracting, from the database, the information about the inspecting object; using the extracted information for automatically editing a text identification header in connection with the inspecting object; and merging the text identification header with the inspection video in connection with the inspection object.
  • a system for creating an identification header using a database to automatically extract information in connection with an inspecting object comprising:
  • An inspection imaging system mounted on a mast supported by a support member to inspect the inspecting object; a storage unit containing information about a given group of inspecting objects; a select module connected to the storage unit to select the inspecting object among the given group of inspecting objects in the storage unit; a header edit module connected to the select module to edit an identification header in connection with the inspecting object; and a video merge module connected to the header edit module to merge the edited identification header with an inspection video in connection with the inspecting object.
  • an inspection imaging system mounted on a mast supported by a support member, the imaging system comprising: a camera with an electronically controllable high magnification ratio zoom to perform inspections both from close up and from a distance; at least five light projectors to provide necessary lighting in the underground conduit; and a housing containing the camera and the light projectors, the camera being centered in the housing and the light projectors surrounding the camera.
  • a method of inspecting an inspection object comprising steps of: determining appropriate optical composition of light to project as a function of an imaging environment; selecting appropriate optical filters as a function of the appropriate optical composition of light to project; placing the selected optical filters in front of light projectors of the inspection system, such that light projected by the light projectors on the inspection object is filtered by effect of the placed optical filters; acquiring an image of the inspection object; and analyzing the acquired image as a function of the optical composition of the projected light.
  • the inspection system comprising light projectors
  • it comprises a power supply converter located in proximity of the light projectors, the power supply converter receiving a 48 volts current via a 48 volts cable connected to a remote power supply unit and converting the 48 volts to a 12 volts current in order to supply the light projectors.
  • the camera can be an analog camera having a controllable zoom, controllable orientation and controllable lighting for illuminating and imaging the conduit.
  • the output video signal is an output analog video signal.
  • the server can be part of a field relay unit providing power to the camera, the lighting and positioning motors, the field relay unit being connected to the camera to provide control signals and receive the output analog video signal from the camera and to the workstation via a data bus.
  • the server comprises: a CODEC device receiving the output analog video signal and converting the output analog video signal into a digital video signal and compressing the digital video signal for storage; and a monitor image generator for sending a live monitor image from the camera to the workstation over the data bus.
  • the inspection systems of the present invention preferably comprise motors mounted on the mast to mechanically control orientation of the camera with respect to the mast.
  • the at least one set of the attribute values comprises a sequence in time of a group of sets of the attribute values.
  • the navigation template can represent a marked state of attributes and the step of sending the at least one set of attribute values can comprise sending one set of attribute values defined by the marked state.
  • the step of selecting a navigation template preferably comprises selecting the navigation template as a function of a type of the inspecting object.
  • the system for automatically generating attribute values preferably comprises a state save module connected to the storage unit for storing, as a navigation template, the attribute signals corresponding to a current state.
  • the housing has preferably a common faceplate for both the camera and the light projectors.
  • the housing has preferably a hexagonal shape and preferably comprises cooling fins and at least one thermoelectric cooling device to dissipate heat generated by the light projectors.
  • the housing preferably comprises apertures of standard dimensions that can receive standard 58 millimeter lens filters and inside of which the light projectors are located, such that light projected by the light projectors is filtered by effect of the standard lens filters.
  • the imaging system preferably comprises a mast to support components of the imaging system and motors to mechanically control orientation of the imaging system with respect to the mast.
  • the imaging environment can be a wall of an underground conduit and, in this case, the selection of appropriate optical filters is carried out as a function of at least one of humidity inside the underground conduit and material of the wall such that the acquired image shows defects of the wall.
  • the imaging environment can also be an underground conduit filled with liquid and, in this case, the selection of appropriate optical filters is carried out as a function of at least one of humidity inside the underground conduit and reflection properties of the liquid such that said acquired image shows the underground conduit without light projected by the liquid.
  • the present invention provides a convenient inspection system, which may be mounted on a hitch of a vehicle for conducting remote subsurface inspections from above as previously described.
  • the present invention also provides fast and cost-effective systems and methods to produce comprehensive and detailed assessments of given sections of sewer systems.
  • the present new technique produces perfect detailed documentation to support budgetary requests and master plans. Therefore, it is possible to establish immediate inspection and cleaning priorities while obtaining a "big-picture" view of what needs to be done in the long term.
  • Figure 1 shows a cross-sectional side view of prior art inspection assembly reaching an underground conduit.
  • Figure 2 shows a cross-sectional side view of prior art inspection assembly trying to reach an offset underground conduit.
  • Figure 3 shows a cross sectional front view of an embodiment of the present invention reaching an offset underground conduit.
  • Figure 4 shows a perspective view of an embodiment of the present invention.
  • Figure 5 shows a perspective view of another embodiment of the present invention in action.
  • Figure 6 shows a perspective view of a further embodiment of the present invention.
  • Figure 7 shows a partial cross-section perspective view of an embodiment of the invention in use.
  • Figure 8 shows an exploded perspective view of a vehicle having a hitch as per another embodiment of the invention.
  • Figure 9 is a block diagram of an imaging system according to a preferred embodiment of the invention.
  • Figure 10 is a block diagram of an imaging system according to another preferred embodiment of the invention.
  • Figure 11 is a flow chart of a method of marking a state of controllable attributes of components of an imaging system according to a preferred embodiment of the invention
  • Figure 12 is a block diagram of a system for marking a state of controllable attributes of components of an imaging system and using the marking state to edit and use a navigation template according to a preferred embodiment of the invention
  • Figure 13 is a flow chart of a method of inspection of an underground conduit using a navigation template according to a preferred embodiment of the invention.
  • Figure 14 is a flow chart of a method of creating an identification header using a database to automatically extract information in connection with an inspected underground conduit according to a preferred embodiment of the invention
  • Figure 15 is a block diagram of a system for creating an identification header using a database to automatically extract information in connection with an inspected underground conduit according to a preferred embodiment of the invention
  • Figure 16 is a flow chart of a method of inspecting an inspection object using optical filters.
  • the imaging system used in the present invention is not a regular imaging system that can be hold over a shoulder but is a special imaging system mounted on a mast supported by a support member that is usually fixed to an inspection truck.
  • an imaging system such as underground conduits and railroad bridge support structures.
  • imaging system it should be understood that it is referred to the part of the inspection system that is placed inside the inspecting underground conduit for imaging.
  • the “imaging system” does not include components that do not constitute a part of the system placed inside the conduit for inspection.
  • inspection system it should be understood that it is referred to the whole system used for inspection. This comprises the imaging system as well as other components used directly or indirectly in connection with the "imaging system”.
  • Figure 1 depicts an example of prior art.
  • an inspection system 10a is mounted to a vehicle 20a having a telescoping mast 50a deployed through a manhole 94a such that a video imaging system 60a is able to reach the lateral conduit 96a.
  • Figure 2 depicts the same example of prior art inspection system as in Figure 1 trying to reach an offset lateral conduit 98a this time. It is apparent that even by positioning the vehicle 20a as close as possible to the side of the manhole 94a, it is not possible for the imaging system 60a to reach the center of the offset lateral conduit 98a.
  • Figure 3 shows an embodiment of the present invention reaching a similarly offset lateral conduit 98 as the offset lateral conduit 98a depicted in the prior art system of Figure 2. It is possible to see that by using the features of the present invention, it is now possible for the video imaging system 60 to reach an offset lateral conduit 98, even when not locating vehicle 20 precisely over the area to be inspected 90.
  • the inspection system 10 is installed on a vehicle 20.
  • the adaptor section 32 of support structure 30 is inserted in the receiver 22 of the hitch 24.
  • a locking pin 26 is used to hold the inspection system solidly connected to the hitch.
  • a device using a set-screw (not shown) to press the support structure 30 against the receiver 22 may be used to remove any play in the assembly.
  • a stabilizing mechanism 34 is used to provide stability to the inspection system 10 such that the images sent by the video imaging system 60 are of good quality.
  • a stabilizing mechanism 34 is used. When not in use, a leg 38 of the stabilizing mechanism 34 is retracted within the support structure 30. When in use, the leg 38 is lowered until it contacts the ground.
  • the inspection system 10 is depicted having an articulating radial arm 40 and a first, second and third pivots 42, 44, 46 having their respective first, second and third rotation axis 42a, 44a and 46a.
  • the articulating radial arm 40 is interrupted at two places by a second pivot 44 and third pivot 46, defining three arm sections 45a, 45b, 45c.
  • the inspection system 10 is installed at the back of a road vehicle 20, the articulating radial arm 40, when folded, does not extend beyond the sides of the vehicle 20.
  • the telescoping mast 50 comprises multiple sections: a fixed outer section 52 and internally nested extending sections 54.
  • the outer section 52 is connected to the articulating radial arm 40.
  • the purpose of the telescoping mast 50 is to lower the video imaging system 60 into the manhole 94 closely to the centerline of lateral conduit.
  • the telescoping mast 50 will be capable of reaching at least 20 feet underground.
  • the lateral conduit is so offset from the manhole 94 that it is not possible for the video imaging system 60 to reach an offset lateral conduit 98 sufficiently well for it to be within the field of view of the imaging system 60.
  • the present invention uses an offsetting mechanism to offset the video imaging system 60 and thereby reach such an offset lateral conduits 98.
  • FIG 4 shows an embodiment of such an offsetting mechanism in the form of a mast pivot 58, connecting the outer section 52 to the articulating radial arm 40.
  • the mast pivot 58 allows the operator to tilt the telescoping mast 50 such that the video imaging system 60 is displaced from its original position, where it was more or less in line with a vertical reference axis 51 located beneath the mast pivot 58, to align with the offset lateral conduit 98.
  • the video imaging system 60 has the inside of the offset lateral conduit 98 in its field of view and is capable of zooming in and out permitting the inspection to proceed.
  • the operator uses the locking mechanisms 70 to lock the telescoping mast 50 at the desired angle.
  • a winch 80 of which cable 82 is connected to the last extending section of the telescoping mast 50, operates its extension or retraction. When the winch 80 unwinds its cable 82, gravity pulls the video imaging system 60 and the extending sections 54 down. To pull the video imaging system 60 back up, the operator rewinds the cable 82.
  • the winch 80 is preferably installed on the telescoping mast 50, but may be fixed to another part of the inspection system 10 that is convenient.
  • a video imaging system 60 is installed at the lower extremity of the extending section 54 of the telescoping mast 50.
  • the video imaging system 60 may be fixed in many ways to the extremity of extending section 54: it may be rigidly fixed, it may be rotatably fixed such as to provide rotation of the video imaging system 60 around the extending axis 56, or it may use an articulation 112 such as to provide any angular movement of the video imaging system 60 with respect to the extending axis 56. Installed in this manner, the video imaging system 60 is the lowest point of the inspection system 10 and can best reach the inside of underground conduits.
  • the video imaging system 60 uses a camera 62 equipped with a relatively high magnification ratio to be capable to perform inspections both from close up and from a distance.
  • the camera uses a 26x optical zoom combined with a 12x numerical zoom.
  • the video imaging system 60 is equipped with an array of light projectors 64 to provide necessary lighting.
  • the camera 62 and light projectors 64 are mounted in a lightweight housing having fins to dissipate heat generated by the light projectors 64.
  • the camera 62 is mounted near the center of the housing 66 with the array of light projectors 64 surrounding it. This design provides the advantage of minimizing shadows captured by camera 62. A further advantage is that this design is very compact.
  • the housing 66 of the video imaging system 60 should be lightweight, resistant to corrosion and watertight. Aluminum is preferably used.
  • Images obtained by the camera 62 are relayed through wiring, or wirelessly, to the video equipment inside the vehicle for analysis. Alternatively, they could be recorded on a medium (CD, DVD, hard disk, etc) or sent remotely for analysis. Images obtained may be analyzed to determine whether problems such as cracks, blockage, and root infiltration exist. If no problem is detected, then the inspection system 10 may be moved quickly to another area to perform another inspection. On the other hand, if a problem is detected, a pipe crawler or other invasive type of inspection may be performed to obtain the details necessary to remedy the situation. This way, the time of setting up and operating a pipe crawler or similar device is not wasted on areas that are in acceptable condition.
  • a display 100 is mounted on the outer section 52 of the telescoping mast 50 to allow the operator to visualize where the video imaging system 60 is located. Images from the camera 62 are relayed to the display 100.
  • the display 100 may alternatively be mounted on another part of the inspection system 10.
  • the display 100 is preferably mounted at eye level either on the telescoping mast 50 or on a section of the inspection system 10 close to it.
  • the inspection system 10 is installed on a vehicle 20 having a hitch 24.
  • the adaptor section 32 of support structure 30 is inserted in the receiver 22 of the hitch 24.
  • a locking pin 26 is used to hold the inspection system 10 solidly connected to the hitch 24.
  • a standard commercially available trailer hitch having a square cross section receiver is used.
  • different models may be used, including non-standard ones, provided that the adaptor section 32 matches the receiver 22.
  • the fact that the inspection system 10 may be adapted to fit a hitch 24 having a standard receiver provides many benefits. For example, the inspection system 10 may be easily installed on, or removed from, in a matter of minutes, various vehicles equipped with a standard hitch having the right receiver.
  • the articulating radial arm 40 and first pivot 42 allow the lateral displacement of telescoping mast 50 and video imaging system 60. Indeed, the operator no longer has to move his vehicle as close to the area to be inspected 90. This feature is extremely useful when the area to be inspected 90 is, for instance, displaced away from the road. The operator may just park his vehicle 20 by the side of the road and extend the articulating radial arm 40 until the telescoping mast 50 is located above the manhole 94. Furthermore, the more arm sections the articulating radial arm 40 has, the more easily the telescoping mast 50 may be deployed around obstacles and the farther from the vehicle 20 it can reach.
  • the first arm section 45a of the articulating radial arm 40 is connected at one end to the support structure 30 through first pivot 42 and at the other end to the second arm section 45b of articulating radial arm 40 through second pivot 44.
  • the third arm section 45c of articulating radial arm 40 is connected at one end to the other end of the second arm section 45b through third pivot 46 and at its other end to the telescoping mast 50 through both fourth pivot 48 and mast pivot 58.
  • fourth pivot 48 is used to provide added maneuverability of the telescoping mast 50 by allowing both the telescoping mast 50 and its mast pivot 58 to rotate around the fourth rotation axis 48a.
  • the rotation axis of pivot 48 is preferably oriented coaxially with the third arm section 45c of the articulating radial arm 40 and perpendicularly to the mast pivot 58.
  • the mast rotation axis 58a of mast pivot 58 is preferably oriented horizontally.
  • Pivots such as first pivot 42
  • Pivots may use different types of elements to provide rotation: ball bearings, taper bearings and bushings, to name a few. Since the construction of pivots is well know in the art, it will not be covered in further detail here.
  • One or many locking mechanisms 70 may be use to prevent the pivots from rotating.
  • a locking mechanism 70 is used at each pivot location to prevent it from rotating both when the inspection system 10 is stored or when the video imaging system 60 is in use. In the latter case, it is important to provide a stable platform for the video imaging system 60, especially when the camera 62 zooms in with its powerful zoom.
  • Each locking mechanism 70 is provided with a handle 72 such that they are easily operated by the operator.
  • the articulating radial arm 40 may fold on itself, allowing for a very compact storage position. In the present configuration, all arm sections 45 a, 45b, 45c of the articulating radial arm 40 fold on the same vertical plane, one section above each other. Once deployed, the articulating radial arm 40 becomes approximately as long as the sum its three arm sections 45, a, 45, b, 45c, providing added range to reach the area to be inspected 90.
  • Figure 5 depicts an alternative embodiment of the invention that includes a second offsetting mechanism. Similar components are given like reference numbers and their description will not be repeated.
  • the second offsetting mechanism of the inspection system 10 takes the form of a locating arm 110 pivotally connected at the tip of the extending section 54 of the telescoping mast 50.
  • This locating arm 110 is provided with articulations 112 and 114 at each end such that it is possible to laterally offset the video imaging system 60 from the mast reference axis 51 such that the video imaging system 60 is located at the desired location for viewing the interior of the offset lateral conduit 98.
  • Both offsetting mechanisms, namely, the mast pivot 58 and the locating arm 110 may be jointly present on the inspection system. This embodiment provides the maximum flexibility in being able to reach offset lateral conduits. Alternatively, for cost considerations for example, only one of the two offsetting mechanisms may be present on the inspection system 10.
  • Figure 6 depicts an embodiment where only the locating arm 110 is present.
  • Different offsetting mechanisms could also be used as an alternative to the locating arm 110.
  • the video imaging system 60 could be mounted on a mechanism that slides perpendicularly to the mast extension axis 56, or a scissor type of mechanism could also be used to laterally project the video imaging system 60 in an offset lateral conduit 98.
  • Many different dispositions and mechanisms to project the video imaging system 60 laterally from the extending mast 50 would be apparent to one skilled in the art, and are all intended to be covered by the present invention.
  • Figure 7 highlights the advantages of the invention in use.
  • the operator drives to the area to be inspected 90 and parks his vehicle 20 nearby. If the inspection system 10 is not readily installed, the operator would install it in one of the receivers 22 of the hitches 24 on the vehicle 20.
  • the operator then connects a power supply to the video imaging system 60, to the winch 80 and connects the wiring 68 between the camera 62 and the imaging processing equipment 120.
  • the manhole cover 92 is removed to gain access to the manhole 94. He then lowers the video imaging system 60 in the manhole 94 using the winch 80.
  • the operator uses the winch 80, and all adjustments provided by the different pivots 42, 44, 46, 48 and 58 to adequately position the camera 62 at the center of the offset lateral conduit 98 to be inspected.
  • the operator could adjust articulations 112 and 114 to adequately position locating arm 110 and video imaging system 60. If the lateral conduit 98 were not offset from the manhole 94, the operator may not have to use mast pivot 58.
  • the camera 62 is then zoomed to obtain an image at the desired magnification. Once the inspection is finished, the video imaging system 60 is pulled back up, the articulating radial arm 40 is folded back into storage position and the manhole cover 92 put back in place. The operator may then drive to the next inspection area.
  • the inspection system 10 is remotely controllable. All moveable parts and joints of the system are motorized such that the operator may remotely manipulate the inspection system 10 from within his vehicle 20.
  • the imaging system 60 continuously sends an image to the operator such that he sees where the camera 62 is going. To get a better view of the environment and where the telescoping mast 50 or the articulating radial arm 40 are continuously located, additional cameras may be added at various locations on the inspection system 10.
  • a specially designed hitch 24 as shown in Figure 8.
  • Such a hitch has one receiver 22a facing towards the back and one facing towards each side of the vehicle, 22b and 22c, for a total of three receivers.
  • This design is convenient as it allows the operator to install the inspection system 10 either at the back or at the left or the right of the vehicle 20. This proves to be useful when all manholes to be inspected are located on the same side of the street, or if the operator needs to reach farther away on one side of the vehicle.
  • the hitch 24 shown in Figure 8 shows a receiver normally located towards the back of a vehicle and a square tube placed perpendicularly to the back receiver 22a, defining both lateral receivers 22b and 22c at each of its extremities.
  • the inspection system 10 is connected in the same manner whether it is at the back or on the sides of the vehicle 20.
  • the hitch may have more or less than three receivers and they may be placed at any position, any angle and any height with respect to one another.
  • the inspection system 10 could be equipped with a non-standard adaptor section 32 and fit into a corresponding non-standard receiver 22.
  • the inspection system 10 does not have to be installed on a hitch: indeed, it could be connected to a vehicle 20 either permanently, or through the use of fasteners.
  • the inspection system could be permanently installed on the back, or at the side, of a vehicle.
  • the vehicle used with the invention is a land vehicle such as, without limitation, a car, a truck, a sport utility vehicle, an all-terrain vehicle, a trailer, or even a set of wheels, mounted or not on their own frame, fixed to the support structure 30.
  • the imaging system 246 comprises a camera 230 with controllable attributes, a high magnification ratio zoom with a zoom controller 232, a motor with a motor controller 236 and light projectors 234.
  • the camera 230 can be either a digital or an analog one, but the zoom is necessarily an optical one to be able to provide the required quality of image. It is always possible to have simultaneously a digital and an optical zoom.
  • the light projectors 234 are preferably electronically controllable light projectors to be able to vary their intensity.
  • the imaging system 246 comprises an interface unit
  • the harness 227 comprises a video cable 222 connected to the camera 230, an attribute cable 224 connected to the interface unit 228 and a power cable 226 connected to each of the camera 230, the light projectors 234 and the motor controller 236 of the imaging system 246.
  • the imaging system 246 is controlled manually from the workstation 210 from which an operator sends a control signal via a USB connection 212 to control the camera 230, the camera zoom, the light projectors 234 and the motors.
  • the field relay 216 receives the control signal sent by the workstation 210 and, in consequence, transmits various attribute signals over a single attribute cable 224 to control the different components of the imaging system 246.
  • the attribute signals include attribute values of the camera 230, attribute values of the zoom, attribute values of the light projectors 234 and attribute values of the motors.
  • the imaging system 246 is electrically supplied by the means of a power supply preferably located in the field relay 216.
  • the field relay 216 comprises a 110 volts socket connected to each of the camera 230, the light projectors 236 and the motor controller 236 by a power cable 226.
  • the same power cable 226 is also connected to supply the display 220 located in proximity of the field relay 216.
  • the field relay 216 comprises a video input for receiving, via a first video cable 222, a video signal recorded by the camera 230. It is possible for the field relay 216 to be connected to the workstation 210 by a second video cable 214 to convey the received video signal for storage in the workstation 210.
  • a CODEC device located in the workstation 210 receives the analog video signal, converts it into a digital video signal and then compresses the digital video signal for storage.
  • FIG. 10 shows a video server 250 connected to the field relay 216 by a fourth video cable 248.
  • the video server 250 comprises a CODEC device to receive, convert and compress the received signal.
  • the server comprises several components with special characteristics, such as a video card with a video entry of a very good quality and a hard disk system of type Raid with a minimum speed of 7200 spins/s to store the video data. Furthermore, it is preferable to have a minimum of 512 MB of read-write memory and a motherboard equipped with at least a Pentium IV processor. A server with such characteristics is required to provide a good quality of image. It is also possible, after installation of especially dedicated software, to be connected to the server via a local or a remote connection (ex. USB, WIFI and Internet) in order to control recording and transferring of the video signal.
  • a local or a remote connection ex. USB, WIFI and Internet
  • the field relay 216 comprises a TV output from which the received video signal is conveyed to a display 220 via a third video cable 218.
  • the display 220 can be an analog or a digital one according to if the received video signal is analog or digital.
  • the display 220 is located in the field and displays the video signal recorded by the camera 230.
  • the first utility of displaying the video signal is that it allows the operator to visualize, in real time, the video signal recorded by the camera 230, giving him the possibility to further control in consequence the attributes of the components of the imaging system 246 (i.e. zoom, light intensity, orientation of the camera, brightness of the image, etc.).
  • the interface unit 228 of the imaging system 246 is responsible of all the intelligence of the imaging system 246. Even if it can also be located in the field relay 216, the interface unit 228 is preferably located in the imaging system 246.
  • the interface unit 228 is provided with a microcontroller preferably containing special software using the standard protocol of communication MODBUS that allows receiving and converting signals (i.e.
  • the interface unit 228 receives the attribute signals over the attribute cable 224 and conveys the received attribute signals to their respective output interfaces so that they can be forwarded toward their respective destinations (i.e. camera 230, zoom, light projectors 234 and motors) by the means of various cables.
  • the interface unit 228 transmits the camera attribute values to the camera 230 via a first attribute cable 238, the zoom attribute values to the zoom controller 232 via a second attribute cable 240, the light attribute values to the light projectors 234 via a third attribute cable 242 and the motor attribute values to the motor controller 236 via a fourth attribute cable 244.
  • one of the advantages to locate the interface unit 228 in the imaging system 246 is to decrease the size of the harness 227 between the field relay 216 and the imaging system 246, making it more flexible and easy to work.
  • the light projectors 234 are preferably electronically controllable light projectors comprising a group of projectors surrounding the camera 230.
  • the projectors can be either bulbs or leds.
  • a power supply source with a converter located in their proximity.
  • the light projectors 234 instead of supplying the light projectors 234 from the field relay 216 with 12 volts current, it is possible to supply it with 48 volts current (that requires a thinner cable) and to convert it to 12 volts current with a 48 to 12 volts converter located in the imaging system 246.
  • the system allows memorizing a state of attributes at any instant during inspection, doesn't matter if the system is in an automatic or a manual mode, changing the state of attributes and then setting up the system automatically according to the memorized state of attributes.
  • the motors are equipped with special sensors capable of detecting orientation and position of the imaging system in space. Thereafter, the system memorizes the detected orientation and position of the imaging system. From their side, the attributes of the light projectors, of the zoom and of the camera are continuously monitored, such that when the mark state command is triggered, the system reads and memorizes the last state of attributes of the components of the imaging system.
  • one among the utilities of marking a state is when the imaging system is in an automatic mode and the operator wants to temporally interrupt the automatic mode (for instance, to inspect manually a given zone in the field of view of the camera) and then goes back to it without loosing the state of attributes of the components right before the interruption.
  • the operator By marking the state of the attributes before interrupting the automatic mode of the imaging system, the operator will be able to put the system in a manual mode, change the state of the attributes according to the needs (ex. change the zoom, the intensity of the projectors, the orientation of the camera, etc.) and then set up the system with the same state of attributes as right before the interruption.
  • FIG. 11 there is shown a method of marking a state of controllable attributes of components of an imaging system. Initially, at least a part of the attributes of the system are put in a first state (270, 278 and 286). Following, at least a part of the attributes put in the first state are selected and have their state memorized and stored in a state marker 294 (272, 280 and 288). The attributes values of the components are then changed and put in a second state (274, 282 and 290). Finally, the system selects the marked state and instates the memorized state of the selected attributes (276, 284 and 292).
  • FIG. 12 there is shown a system for marking a state of controllable attributes of components of an imaging system.
  • the system for marking a state of attributes is generally located in the workstation 210 and comprises a navigation motor controller 310, a zoom module 314, a camera setting module 318, a lighting controller 322, a bus interface unit 326, a state saver 328, a state marker 330, a state selector/executer 332.
  • the workstation 210 (that generally comprises the system for marking a state of attributes) is connected to the imaging system 246 via the field relay 218.
  • the navigation motor controller 310 is a module that receives a motor control signal for controlling the motor and sends a motor attribute signal 312 containing motor attribute values to the bus interface unit 326.
  • the motor control signal is generated by an appropriate user-friendly interface, such as a joystick, manipulated by the operator.
  • the zoom module 314 is a module that receives a zoom control signal generated by the operator for controlling the zoom of the camera and sends a zoom attribute signal 316 containing zoom attribute values to the bus interface unit 326.
  • the camera setting module 318 receives a camera control signal generated by the operator for controlling the camera and sends a camera attribute signal 320 containing camera attribute values to the bus interface unit 326.
  • the lighting controller 322 is a module that receives a light control signal generated by the operator for controlling the light projectors and sends a light attribute signal 324 containing light projectors attribute values to the bus interface unit 326. All of the navigation motor controller 310, the zoom module 314, the camera setting module 318 and the lighting controller 322 are preferably software modules.
  • the bus interface unit 326 conveys the received attribute signals (312, 316, 320 and 324) to the imaging system 246 via the field relay 218 in order to control the different components of the imaging system.
  • the operator at the workstation 210 supervises, by the means of the display 220, the change of state of the attributes of the different components. If the operator decides to mark the state of the attributes, the bus interface 326 conveys the attribute signals to the state saver 328 to save the attribute values. Thereafter, the state saver 328 sends these attribute values for storage in the state marker 330.
  • the state selector/executer 332 sends an attribute signal 344 with the memorized state of attributes to the bus interface 326 to be thereafter conveyed to the imaging system 246 to control the different components.
  • the conduit inspection standardization makes it possible to automate conduit inspection systems.
  • the system uses navigation templates especially adapted for various types of inspecting conduits.
  • Each navigation template contains, for a given type of an inspecting conduit, at least one set of predefined attribute values of the components of the imaging system (i.e. attributes of the camera, attributes of the projectors, attributes of the motors, attributes of the zoom, etc).
  • Navigation templates can have one set of attribute values but, generally, they contain a sequence in time of a group of sets of attribute values allowing the inspection system to operate in an automated mode for a given period of time.
  • navigation templates can, partially or totally, be made of one or a group of marked states.
  • a navigation template operates as follows: once the imaging system positioned in the center of the pipe, the operator selects the inspecting conduit type (i.e. the diameter and the type of material) and the system automatically selects and executes a suitable navigation template as a function of the selected inspecting conduit. Thereafter, all the attributes of the components of the imaging system are adjusted automatically. If the given navigation template contains a sequence in time of a group of attribute values, the imaging system will then navigate in an automated mode for a given period of time. The operator visualizes the course of the operation by the means of the display 220 or the workstation 210.
  • the inspecting conduit type i.e. the diameter and the type of material
  • a navigation template that, when executed, activates attributes of only a part of components of an imaging system. This makes it possible to automate only a part of the components of the imaging system (for instance, automating the zoom) and to preserve a manual mode for the other part of the components (for instance, preserving a manual operability to vary the intensity of the projectors and the orientation of the camera).
  • a navigation template can also be interrupted in court of execution while preserving a marker (state marker) memorizing the attribute values of the components of the imaging system right before the interruption. The system also allows the creation of new navigation templates for new types of conduits not envisaged originally by the system.
  • navigation templates are edited 380 and stored 382 in a navigation template server 390 before starting the inspection. Even if navigation templates are usually edited as a function of types of inspecting conduits and stored prior to the inspection, it is always possible to edit navigation templates in the course of inspection, for instance, by marking and memorizing a given state of attributes.
  • the operator selects a given navigation template (among a group of navigation templates) 384 from the navigation template server (that can be the same physical device as the workstation) 390 to be eventually executed 386.
  • the selection of the navigation template is carried out as a function of the type of the inspecting conduit.
  • the attribute values contained in the selected navigation template are sent to the imaging system to automatically navigate the imaging system according the selected navigation template 388.
  • the system changes the previous state of attributes of the components of the imaging system to a new one according to content of the executed navigation template 388.
  • FIG. 12 there is shown a system for inspecting an underground conduit using a navigation template.
  • the system comprises a navigation template editor 334, a navigation template server 336, a navigation template selector 338 and a navigation template executer 340. Normally, all these components are located within the workstation 210.
  • the navigation template editor 334 allows editing new navigation templates and is connected to the navigation template server 336 to store the edited navigation templates.
  • the navigation template editor 334 is also connected to the state maker 330 to receive a marked state when required.
  • the edited navigation templates are usually edited manually and stored prior to the inspection, but it is also possible to edit navigation templates from the marked states of attributes.
  • the navigation template selector 338 allows selecting a given navigation template according to a choice of the operator and it is connected to the navigation template server 336 to select and receive the given navigation template among a group of stored navigation templates.
  • the navigation template executer 340 is responsible for executing the selected navigation template and sending this selected navigation template to the imaging system 246. Therefore, the navigation template executer 340 is connected to the navigation template selector 338 to receive and execute the selected navigation template.
  • the navigation template executer 340 is also connected to the bus interface unit 326 to send to the imaging system an attribute signal 344 containing the selected navigation template 246 for automatically navigating the imaging system 246 according to the selected navigation template.
  • the video generated in connection with a given inspected conduit should be clearly identified.
  • the video file is labeled as a function of the names of the conduit and of the inspection project.
  • the system allows inserting, at the beginning of the introduction video, an introduction video containing identification information about the inspected conduit to clearly identify the latter. Identification information comprises the number, the geographic localization and the type (i.e. material type and dimensions) of the conduit.
  • FIG. 14 there is shown a method of creating an identification header using a database to automatically extract information in connection with an inspected underground conduit.
  • the operator starts by selecting, from a database 398 (i.e. geographical or relational database), the inspected underground conduit 390.
  • the system extracts, from the database 398, information in connection with the inspected underground conduit 392.
  • information comprises the number, the localization and the type of the inspected underground conduit.
  • the system automatically edits a text identification header in connection with the inspected underground conduit 394 and stores the text header in a text header server 400.
  • the system merges the edited identification header with the inspection video in connection with the inspected underground conduit 396.
  • This method being free of any human intervention, editing errors (that usually occur when information is entered manually) are eliminated.
  • this automated method is faster and more reliable than any other manual method used for creating identification headers in connection with conduits.
  • the system spreads automatically the identification information over as many consecutive pages as necessary.
  • FIG. 15 there is shown a system for creating an identification header using a database to automatically extract information in connection with an inspected underground conduit.
  • the system comprises a database 398 (i.e. geographical or relational database), an underground conduit selector 410, a header editor 412, a text header server 400, a video merger 414 and an interface unit 416.
  • the underground conduit selector 410 is connected to the database 398 to select the inspected conduit among a group of conduits and to extract information in connection with the selected underground conduit.
  • the Header editor 412 is connected to the underground conduit selector 410 to receive information about the selected underground conduit. Thereafter, the header editor proceeds to edit an identification header according to the received information and stores the edited identification header in the text header server 400.
  • the video merger 414 is connected to the header editor 412 to receive the edited header.
  • the video merger 414 merges the received identification header with the inspection video in connection with the inspected conduit and sends the resulting video to the interface unit 416 that conveys it to the video server 250 via the field relay 216.
  • the header editor 312 provides the possibility to automatically update the associated identification header as well as the associated inspection video to take into account the new information. An update operation in connection with a given identification header can be repeated as many times as necessary without any risk of deteriorating the quality of the inspection video.
  • the light projectors of the imaging system are preferably electronically controllable light projectors, such that the operator can control their intensities remotely.
  • the system provides a camera with a high magnification zoom surrounded by at least 5 projectors to provide necessary lighting in the inspecting conduit. The reason to place the light projectors all over the circumference surrounding the camera is to be able to provide uniform lighting for all the circumference of the conduit without creating shadow zones in the bottom side of the camera.
  • the light projectors should have an appropriate size such that the circumference on which they stand does not exceed 8 inches to be able to insert the imaging system in narrow places.
  • the camera and the light projectors are preferably contained inside a hexagonal housing with a common faceplate for both the camera and the light projectors.
  • the housing preferably comprises cooling fins and at least one thermoelectric cooling device (ex. Peltier device) to dissipate heat generated by the light projectors.
  • the camera and the light projectors are arranged in such a way that the camera is centered inside the housing and the light projectors surround the camera.
  • the housing comprises apertures of standard dimensions that can receive standard 58 millimeter lens filters and inside of which the light projectors are located, such that light projected by the light projectors is filtered by effect of the standard lens filters in order to improve quality of imaging.
  • the filters are generally chosen as a function of the imaging environment. When the latter is a wall of an underground conduit, the optical filters are generally chosen as a function of material of the wall and the humidity rate inside the underground conduit, such that the acquired image shows clearly defects on the wall.
  • the inspecting conduit is filled with liquid, selection of the optical filters is carried out in considering reflection characteristics of the liquid, such that the acquired image is free of light projected by the liquid.
  • FIG. 16 there is shown a method of inspecting a conduit using optical filters.
  • the operator determines an appropriate chromatic composition of light to project as a function of imaging environment 420.
  • the operator selects appropriate optical filters as a function of the appropriate chromatic composition of light to project 422.
  • the operator poses the selected optical filters in front of light projectors of the inspection system, such that light projected by the light projectors on the inspection object is filtered by effect of the posed optical filters 424.
  • Fifth, the system acquires the image of said inspection object 426.
  • said acquired image is being analyzed as a function of the chromatic composition of the projected light 428.

Landscapes

  • Engineering & Computer Science (AREA)
  • Multimedia (AREA)
  • Signal Processing (AREA)
  • Health & Medical Sciences (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Hydrology & Water Resources (AREA)
  • Public Health (AREA)
  • Water Supply & Treatment (AREA)
  • Investigating Materials By The Use Of Optical Means Adapted For Particular Applications (AREA)
  • Monitoring And Testing Of Nuclear Reactors (AREA)
  • Closed-Circuit Television Systems (AREA)
  • Studio Devices (AREA)

Abstract

La présente invention concerne un appareil servant à effectuer des inspections sous une surface à distance depuis le haut. L'appareil comprend une structure de soutien, un mât télescopique maintenu par un raccord et porté par la structure de soutien, un système de traitement d'image maintenu par une partie extensible du mât télescopique et un mécanisme de décalage. L'appareil peut en outre comprendre un bras radial articulé qui pivote afin de localiser le mât télescopique. La structure de soutien de l'appareil peut également inclure une section d'adaptateur servant à être fixée à un récepteur d'une attache d'un véhicule. La présente invention concerne également un procédé servant à effectuer des inspections sous une surface à distance depuis le haut. Le procédé d'inspection comprend les phases consistant à localiser un point d'accès sur une surface de travail, positionner un appareil servant à effectuer des inspections sous une surface à distance depuis le haut, manipuler le mât télescopique au dessus du point d'accès, l'abaisser et passer en revue des images à partir du système de traitement d'image.
EP06804735A 2005-11-16 2006-11-16 Appareil et procede servant a effectuer une inspection video a distance depuis le haut Withdrawn EP1960763A4 (fr)

Priority Applications (1)

Application Number Priority Date Filing Date Title
EP10185956A EP2288160A3 (fr) 2005-11-16 2006-11-16 Appareil et procédé pour la réalisation d'une inspection vidéo à distance depuis une position supérieure

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
US11/274,316 US20070109416A1 (en) 2005-11-16 2005-11-16 Apparatus and method for remote inspection of a structure using a special imaging system
US11/280,201 US8525877B2 (en) 2005-11-17 2005-11-17 Apparatus and method for conducting remote video inspection from above
US11/280,202 US8773525B2 (en) 2005-11-17 2005-11-17 Apparatus and method for conducting remote video inspection from above
PCT/CA2006/001871 WO2007056855A1 (fr) 2005-11-16 2006-11-16 Appareil et procede servant a effectuer une inspection video a distance depuis le haut

Publications (2)

Publication Number Publication Date
EP1960763A1 true EP1960763A1 (fr) 2008-08-27
EP1960763A4 EP1960763A4 (fr) 2011-03-23

Family

ID=38048248

Family Applications (2)

Application Number Title Priority Date Filing Date
EP06804735A Withdrawn EP1960763A4 (fr) 2005-11-16 2006-11-16 Appareil et procede servant a effectuer une inspection video a distance depuis le haut
EP10185956A Withdrawn EP2288160A3 (fr) 2005-11-16 2006-11-16 Appareil et procédé pour la réalisation d'une inspection vidéo à distance depuis une position supérieure

Family Applications After (1)

Application Number Title Priority Date Filing Date
EP10185956A Withdrawn EP2288160A3 (fr) 2005-11-16 2006-11-16 Appareil et procédé pour la réalisation d'une inspection vidéo à distance depuis une position supérieure

Country Status (4)

Country Link
EP (2) EP1960763A4 (fr)
AU (1) AU2006315034A1 (fr)
CA (2) CA2716440C (fr)
WO (1) WO2007056855A1 (fr)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN111115030A (zh) * 2019-12-30 2020-05-08 安徽银龙泵阀股份有限公司 一种具有防堵塞功能的泵阀管道

Families Citing this family (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP3111043A4 (fr) 2014-04-30 2017-10-04 Halliburton Energy Services, Inc. Surveillance d'équipement à l'aide d'une vidéo améliorée
EP3108651A4 (fr) 2014-04-30 2017-10-11 Halliburton Energy Services, Inc. Surveillance souterraine par vidéo perfectionnée
DE102016121286B4 (de) * 2016-11-08 2021-07-08 Ibak Helmut Hunger Gmbh & Co Kg Verfahren zum Ausrichten eines Kanalspiegels in einem Kanalrohr und Kanalspiegel
CA3053026A1 (fr) 2018-09-07 2020-03-07 Signalisation D'urgence Rh Inc. Dispositif d`alarme escamotable et procede pour emettre un signal lumineux
CN109361901B (zh) * 2018-11-19 2021-06-01 国网福建省电力有限公司 水电站调压井内部结构成像检查装置
CN112097042B (zh) * 2020-09-17 2021-05-11 稷米(广州)科技有限公司 一种通信设备
CN113596299B (zh) * 2021-07-20 2023-04-07 深圳市研迪数字技术有限公司 一种具有自清洁功能的高清摄像远程监控设备

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1997008633A1 (fr) * 1995-08-29 1997-03-06 Gmi, Llc Procede d'acces aleatoire a des images enregistrees et systeme d'inspection sur site dans lequel ce procede est utilise
EP1051037A2 (fr) * 1999-05-04 2000-11-08 Everest-VIT, Inc. (a New Jersey Corporation) Procédé et système d'inspection
WO2005026919A2 (fr) * 2003-09-11 2005-03-24 Bradford Addison Clough Systeme et procede d'acquisition et d'analyse de donnees specifiques au temps a l'emplacement

Family Cites Families (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB1240837A (en) * 1968-05-16 1971-07-28 Rank Organisation Ltd Improvements relating to camera systems
CA2309018A1 (fr) * 2000-05-12 2001-11-12 R. Michael Mcgrew Appareil ameliore d'inspection des egouts lateraux
EP1288694B1 (fr) * 2001-04-05 2011-06-08 Scalar Corporation Camera et unite pour camera
US7322745B2 (en) * 2002-07-23 2008-01-29 Rapiscan Security Products, Inc. Single boom cargo scanning system
WO2005016692A2 (fr) * 2003-07-03 2005-02-24 Chief Environmental Services I Appareil et procede d'inspection de canalisations d'egout utilisant des petits vehicules mobiles
EP1661393A4 (fr) * 2003-09-04 2010-06-02 Chapman Leonard Studio Equip Tete de camera stabilisee trois axes

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1997008633A1 (fr) * 1995-08-29 1997-03-06 Gmi, Llc Procede d'acces aleatoire a des images enregistrees et systeme d'inspection sur site dans lequel ce procede est utilise
EP1051037A2 (fr) * 1999-05-04 2000-11-08 Everest-VIT, Inc. (a New Jersey Corporation) Procédé et système d'inspection
WO2005026919A2 (fr) * 2003-09-11 2005-03-24 Bradford Addison Clough Systeme et procede d'acquisition et d'analyse de donnees specifiques au temps a l'emplacement

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
See also references of WO2007056855A1 *

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN111115030A (zh) * 2019-12-30 2020-05-08 安徽银龙泵阀股份有限公司 一种具有防堵塞功能的泵阀管道

Also Published As

Publication number Publication date
CA2716440A1 (fr) 2007-05-24
CA2716440C (fr) 2014-02-11
AU2006315034A1 (en) 2007-05-24
EP1960763A4 (fr) 2011-03-23
CA2629939A1 (fr) 2007-05-24
EP2288160A3 (fr) 2011-03-30
EP2288160A2 (fr) 2011-02-23
WO2007056855A1 (fr) 2007-05-24

Similar Documents

Publication Publication Date Title
CA2716440C (fr) Appareil et procede servant a effectuer une inspection video a distance depuis le haut
US8773525B2 (en) Apparatus and method for conducting remote video inspection from above
US8024066B2 (en) Autonomous inspector mobile platform
EP1361001B1 (fr) Procédé et dispositif pour inspecter des tuyaux de canalisation
DE60205353T2 (de) Robotersystem zur inspektion von gasleitungen
US7009698B2 (en) Inspection system and method
JP2004509321A (ja) パイプラインの欠陥を検出する装置および方法
US7720570B2 (en) Network architecture for remote robot with interchangeable tools
US8525877B2 (en) Apparatus and method for conducting remote video inspection from above
US7460980B2 (en) Method for the control of a pipe inspection system and for the evaluation of the inspection data
US11635391B2 (en) Systems and methods for inspecting pipelines using a pipeline inspection robot
US7420587B2 (en) Apparatus and method for inspecting sewer lines using small mobile vehicles
KR102436541B1 (ko) 협소지역용 도로지반조사 장치
US20100066844A1 (en) Apparatus and method for remote inspection of a structure using a special imaging system
JP4535974B2 (ja) 天地補正機能を有する画像処理装置及びその画像処理装置を搭載する管路点検システム及び管路画像の処理方法。
EP3798622B1 (fr) Systèmes et procédés d'inspection de canalisations à l'aide d'un système d'imagerie robotique
JPH0752587Y2 (ja) 下水道管等の管路検査装置
KR200284880Y1 (ko) Gps를 이용한 관로탐색 제어차량의 위치정보 표시장치
US20220145608A1 (en) System and method for inspection of a sewer network
KR100478330B1 (ko) 관로의 경사도 측정장치
KR200394248Y1 (ko) 관로 조사용 자주차의 다방향 디스플레이 시스템
JP3045982U (ja) 管路点検用具
KR100670825B1 (ko) 관로 조사용 자주차의 다방향 디스플레이 시스템
McCullouch Video Camera Inspection System

Legal Events

Date Code Title Description
PUAI Public reference made under article 153(3) epc to a published international application that has entered the european phase

Free format text: ORIGINAL CODE: 0009012

17P Request for examination filed

Effective date: 20080616

AK Designated contracting states

Kind code of ref document: A1

Designated state(s): AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HU IE IS IT LI LT LU LV MC NL PL PT RO SE SI SK TR

DAX Request for extension of the european patent (deleted)
A4 Supplementary search report drawn up and despatched

Effective date: 20110217

RIC1 Information provided on ipc code assigned before grant

Ipc: B60D 1/07 20060101ALI20110211BHEP

Ipc: E02D 29/12 20060101ALI20110211BHEP

Ipc: G01D 11/30 20060101ALI20110211BHEP

Ipc: G01N 21/954 20060101AFI20070711BHEP

Ipc: H04N 7/18 20060101ALI20110211BHEP

Ipc: G06F 17/30 20060101ALI20110211BHEP

Ipc: G01N 21/84 20060101ALI20110211BHEP

STAA Information on the status of an ep patent application or granted ep patent

Free format text: STATUS: THE APPLICATION IS DEEMED TO BE WITHDRAWN

18D Application deemed to be withdrawn

Effective date: 20120105