The invention relates to an inspection and repair module for an internal side wall of a vertically erected structure, with the module including a carrier for supporting at least one data recording mechanism and being securable to a hoist, and for an inspection and repair module for an internal wall of a conduit with the module including propulsion means comprising a set of driven tracked wheels controllable by a controller carried by the carrier and configured to provide, within a conduit, longitudinal forward and reverse motion.

The present invention relates to an optical element for use in a camera system for the inspection of passageways, a camera system for the inspection of passageways and a method of illuminating a passageway during inspection with a camera. An optical element for use in a camera system for the inspection of passageways comprises a first optical portion arranged to transmit light into a camera, a second optical portion arranged to transmit light emitted from a light source, the second optical portion located adjacent the first optical portion, and barrier means arranged to prevent light being transmitted from the second optical portion into the first optical portion.

Internal components of power generation machinery, such as gas turbine engines, are inspected with a spherical, optical-camera inspection system, mounted within a camera housing on a distal end of a compact diameter, single-axis inspection scope. The inspection scope includes nested, non-rotatable telescoping tubes, which define an extension axis. Circumscribing, telescoping tubes have anti-rotation collars, which are in sliding engagement with extension tracks on a circumferential surface of an opposing, nested tube, for ease of extension and retraction of the camera during visual inspections of power generation machinery. The camera is advanced and/or retracted along a scope extension axis by nested, drive tubes, which incorporate at least one external drive screw on a circumscribed drive tube and corresponding female threads formed in a circumscribing drive tube. The spherical camera has a 360-degree field of view, and captures images without rotation about the scope extension axis.

A portable camera controller for use with a pipe inspection system is disclosed. The controller may include an onboard display, USB ports, wireless capability, and a built-in transmitter for energizing a pipe-inspection cable for tracing purposes. The camera controller may be configured to support auto-logging and automatic report generation of pipe inspection operations and associated locating operations. The camera controller may be self-grounding using conductive and/or capacitive grounding circuits and an associated transmitter may be used without a separate grounding stake through use of the conductive and/or capacitive grounding circuits.

A pipeline inspection device including a housing, an antenna, an imaging device having one or more lenses, two diaphragms extending from the housing and distal to one another along the length of the housing, the two diaphragms sharing a longitudinal axis with the housing, a processor, a storage device in communication with the processor, and a memory in communication with the processor, storing a machine learning algorithm and instructions to be executed by the processor, wherein the antenna is operable to communicate with a remote transceiver, the remote transceiver being located on a pipeline through which the pipeline inspection device travels. Also disclosed herein are systems and methods for using the same.

A pipe inspection system including a camera head, a push-cable, and a controller platform for use in inspecting pipes or other cavities is disclosed.

Camera heads and associated systems, methods, and devices for inspecting and/or mapping pipes or cavities are disclosed. A camera head may be coupled to a push-cable and may include one or more image sensors to capture images and/or videos from interior of the pipe or cavity. One or more multi-axis sensors may be disposed in the camera head to sense data corresponding to movement of the camera head within the pipe or cavity. The images and/or videos captured by the image sensors may be used in conjunction with the data sensed by the multi-axis sensors to generate information pertaining to the pipe or cavity may be generated.

Flexible magnetic cores for generating magnetic fields are disclosed. The flexible cores may include an elongate resiliently deformable rod and a flexible elongate structure of a high permeability ferromagnetic material disposed around the elongate resiliently deformable rod.

A borescope may include a housing including a transparent viewing window, a bumper surrounding at least a portion of a periphery of the transparent viewing window, wherein the bumper is configured to be pressurized by a fluid, and at least one imaging assembly configured to visualize a field of view exterior of the housing through the transparent viewing window.

There is provided an imaging control device, an imaging control method, a program, and an imaging system that enable easy change of a direction in which an image of a subject is captured in a case where imaging is performed using an optical member whose observation optical axis is inclined with respect to a central axis. The imaging control device includes: a rotation axis setting unit that sets a rotation axis on the basis of a pivot point and a point of interest on the subject, the pivot point serving as a fulcrum of the rod-shaped optical member whose observation optical axis is inclined with respect to the central axis and being not positioned on the observation optical axis; and a posture control unit that rotates the optical member around the rotation axis. The present technology can be applied to, for example, an endoscope system.