One embodiment provides a pipe inspection robot, including: a chassis configured to traverse through an interior of a water or sewer pipe; a water quality probe comprising a first end that couples to the chassis and a sensing end distal thereto; an electric motor configured to reposition the sensing end of the water quality probe with respect to the chassis; said electric motor acting to move the sensing end of the water quality probe to reposition the sensing end proximate to fluid containing water located proximate to a bottom part of the chassis; the sensing end configured to contact the fluid containing water for contact sensing of water quality data. Other aspects are described and claimed.

One embodiment provides a pipe inspection robot, including: a chassis configured to traverse through an interior of a water or sewer pipe; a water quality probe comprising a first end that couples to the chassis and a sensing end distal thereto; an electric motor configured to reposition the sensing end of the water quality probe with respect to the chassis; said electric motor acting to move the sensing end of the water quality probe to reposition the sensing end proximate to fluid containing water located proximate to a bottom part of the chassis; the sensing end configured to contact the fluid containing water for contact sensing of water quality data. Other aspects are described and claimed.

Provided is a pipe interior inspection robot that has characteristics of having an extremely simple device structure to easily achieve dustproof and waterproof properties, being able to pass through a pipe bent in any direction, and enabling the selection of the advancing direction.

A pipe interior inspection robot for inspecting the inside of a pipe branched from a pipe header, the robot including: 1) a moving means having a structure capable of being introduced from a pipe base, which is an inlet of the pipe header, and capable of moving in the pipe header and being fixed to a pipe wall inside the pipe header at a desired position; 2) a mechanism for specifying a position of a pipe to be inspected; and 3) a mechanism for inspecting a condition inside the pipe to be inspected.

A speed control apparatus for an inline pipeline inspection tool includes a body configured to be moved by a compressible product moving through a pipeline and a speed control mechanism supported by the body. The speed control mechanism includes a contact member that is positionable against an inner surface of the pipeline and an actuator configured to act on the contact member to adjust a speed of the body when the speed deviates from a predetermined speed. The speed control apparatus forms a drive system that provides forward propulsion to prevent the tool from slowing or stopping due to a problematic feature in the pipeline. The speed control apparatus also forms a brake system that minimizes overspeed conditions that can occur when built-up pressure initially dislodges the tool from the problematic feature in the pipeline.

A device for traversing a conduit includes a body having a first member that is receivable within a second member. The first member is slidable relative to the second member. A first actuator is coupled to a first end of the body. A second actuator is coupled to a second end of the body. A third actuator is coupled to the body between the first actuator and the second actuator. The third actuator is also spaced apart from the first actuator and the second actuator. The device also includes a pneumatic system that is configured to change the pressure of the actuators.

A device for traversing a conduit includes a body having a first member that is receivable within a second member. The first member is slidable relative to the second member. A first actuator is coupled to a first end of the body. A second actuator is coupled to a second end of the body. A third actuator is coupled to the body between the first actuator and the second actuator. The third actuator is also spaced apart from the first actuator and the second actuator. The device also includes a pneumatic system that is configured to change the pressure of the actuators.

A crawler comprising: (a) a body; (b) a camera head in or connected to said body; (c) a plurality of motorized hub assemblies; and (d) a plurality of legs, each of said plurality of legs having a first end and a distal second end, said first end being connected to said body, and said second end being connected to one of said plurality of motorized hub assemblies, wherein said legs are actuatable to define a minimum extended position and an extended position, wherein said motorized hub assemblies are close to said body in said minimum extended position, and distal from said body in said extended position.

A crawler comprising: (a) a body; (b) a camera head in or connected to said body; (c) a plurality of motorized hub assemblies; and (d) a plurality of legs, each of said plurality of legs having a first end and a distal second end, said first end being connected to said body, and said second end being connected to one of said plurality of motorized hub assemblies, wherein said legs are actuatable to define a minimum extended position and an extended position, wherein said motorized hub assemblies are close to said body in said minimum extended position, and distal from said body in said extended position.

A robotic apparatus comprising first, second, and third wheel assemblies, and a clamping mechanism configured to apply a force for urging the second wheel and the third wheel to pivot in opposing directions towards a plane of the first wheel for securing the first wheel, the second wheel, and the third wheel to the pipe, each wheel assembly including an alignment mechanism for adjusting an orientation of the wheels to allow the robotic apparatus to move along a straight path or a helical path on the pipe. A method for navigating an obstacle on a pipe comprising advancing the robotic apparatus along a helical pathway on the pipe to position an open side of the robotic apparatus in longitudinal alignment with the obstacle, and advancing the robotic apparatus along a straight pathway on the pipe such that the obstacle passes unobstructed through the open side of the robotic apparatus.

A robotic apparatus comprising first, second, and third wheel assemblies, and a clamping mechanism configured to apply a force for urging the second wheel and the third wheel to pivot in opposing directions towards a plane of the first wheel for securing the first wheel, the second wheel, and the third wheel to the pipe, each wheel assembly including an alignment mechanism for adjusting an orientation of the wheels to allow the robotic apparatus to move along a straight path or a helical path on the pipe. A method for navigating an obstacle on a pipe comprising advancing the robotic apparatus along a helical pathway on the pipe to position an open side of the robotic apparatus in longitudinal alignment with the obstacle, and advancing the robotic apparatus along a straight pathway on the pipe such that the obstacle passes unobstructed through the open side of the robotic apparatus.