A system and method for internally inspecting a tubular composite part so as to identify and measure adhesive flow therewithin are provided, along with an endpoint adapter assembly of a near infrared (NIR) spectrometer. The system includes an end point adapter that fits within and maintains a consistent cross-sectional position within the tubular composite part. The system also includes a plurality of optical fibers extending radially outward from the end point adapter. The end point adapter moves longitudinally through the tubular composite part and receives light with the plurality of optical fibers following interaction of the light with the tubular composite part. The system further includes a NIR imaging spectrometer configured to disperse the light being collected by the plurality of optical fibers across an NIR spectrum and a NIR camera configured to generate images of the tubular composite part based on dispersed light.

A shape measurement system and method for a three-dimensional shape of a linear object over a long distance with high resolution. The shape measurement system comprises: a multicore optical fiber having a center core positioned in the center of the cross section thereof and three or more outer peripheral cores positioned at equal intervals concentrically with respect to and outside of the center core; a measurement device for measuring the backward Brillouin scattered light distribution in the propagation direction of each core of the multicore optical fiber; and an analysis device for calculating position coordinates, in three-dimensional space, of a linear structure having an unknown three-dimensional shape from the backward Brillouin scattered light distributions of a multicore optical fiber positioned along the linear structure having an unknown three-dimensional shape and a multicore optical fiber positioned along a linear structure having a known three-dimensional shape.

Methods, systems, devices, and products for evaluating a downhole fluid in a borehole intersecting an earth formation. Methods include using ultrasonic irradiation to produce sonoluminescence from cavitation in a volume of the fluid; obtaining spectral information from measurement of the sonoluminescence with a light-responsive device; and estimating a parameter of interest of the fluid from the spectral information. The parameter may be a composition of the fluid or concentration of: i) at least one chemical element in the volume; i) at least one molecular element in the volume. Methods include deconvolving a response spectrum by using one or more separately determined standard spectra, or estimating the parameter of interest using spectral lines represented by the spectral information. Methods may include using an optically transparent ultrasonic transducer to produce the cavitation at the interface of the transducer, with optically transparent ultrasonic transducer between the interface and the light-responsive device.

A system includes a vessel floating on a body of water. The system also includes at least one conduit extending from the vessel to below the body of water. The system also includes a scanning device disposed within the at least one conduit. The scanning device includes at least one two-dimensional (2D) line scanner and a rotary encoder coupled to the at least one 2D line scanner. The scanning device is configured to generate three-dimensional (3D) image data of a surface of the at least one conduit or at least one component disposed within the at least one conduit.

A boroscope has a first end and a second end and the first end of the boroscope has an optical fiber, a light source, a lens, a beam expander and a transmissive diffractive optical element. The optical fiber extends from the first end of the boroscope to the second end of the boroscope. A laser optical fiber extends from the lens at the first end of the boroscope to the second end of the boroscope and a laser source is arranged to direct a laser beam into the laser optical fiber. The beam expander is provided between the laser optical fiber and the lens and the lens is provided between the beam expander and the transmissive diffractive optical element. The transmissive diffractive optical element is arranged to produce a laser beam with a predetermined shape and a focal length probe extends from the first end of the boroscope.

A system includes a vessel floating on a body of water. The system also includes at least one conduit extending from the vessel to below the body of water. The system also includes a scanning device disposed within the at least one conduit. The scanning device includes at least one two-dimensional (2D) line scanner and a rotary encoder coupled to the at least one 2D line scanner. The scanning device is configured to generate three-dimensional (3D) image data of a surface of the at least one conduit or at least one component disposed within the at least one conduit.

A guide tube guides a cable of an internal observation device into a pipe bore. The cable is pushed into the pipe bore to force an observation image capturing part provided proximate a tip end of the cable to approach a portion to be observed when performing internal observation of the pipe bore of a pipe-like structure with the internal observation device. The guide tube includes: an outside wall having an outside diameter of the guide tube that is substantially equal to an internal diameter of the pipe bore; and an internal wall having an internal diameter of the guide tube that is substantially equal to an outside diameter of the cable

A cylindrical shell detection method includes generating a first and a second terahertz transmitting electromagnetic waves; detecting a plurality of first terahertz reflected electromagnetic waves reflected by the first terahertz transmitting electromagnetic wave incident in a plurality of inner interface layers of a cylindrical shell; detecting a plurality of second terahertz reflected electromagnetic waves reflected by the second terahertz transmitting electromagnetic wave incident in a plurality of outer interface layers of a cylindrical shell; measuring a plurality of first characteristic signals according to the first terahertz transmitting electromagnetic waves and the first terahertz reflected electromagnetic waves to determine a plurality of first characteristics of the plurality of inner interface layers; and measuring a plurality of second characteristic signals according to the second terahertz transmitting electromagnetic waves and the plurality of second terahertz reflected electromagnetic waves to determine a plurality of second characteristics of the plurality of inner interface layers.

An intrusive wear sensor (1) comprises one or more optical fibres (22, 122, 222) mounted in an intrusive probe housing (20), one end of the one or more optical fibres being adapted to be directly exposed to a process fluid in use. An electronics module (13) is mounted in the wear sensor and separated from the process fluid flow (14) by a barrier (16). The electronics module (13) comprises a light transmitter (27) to transmit a light beam (23) along the one or more optical fibres to an interface (21, 121, 221) with the process fluid; and a light detector (26) to receive the reflected light (24), whereby a change in length of the one or more optical fibres (22, 122, 222) may be determined from a change in detected time of travel of the light beam (23, 24).

A non-contact optical probe for inspecting an inside surface of a cylindrical workpiece includes a laser source that emits an incident light beam, a polarizing beam splitter that transmits one polarization of the incident beam and reflects the opposite polarization, and a quarter wave plate that together with the polarizing beam splitter separates back reflected return light from the incident laser beam. The non-contact optical probe further includes an optical system that directs the incident laser beam onto the cylinder surface and directs reflected light from the surface back to the beam splitter, and at least one detector that receives a portion of the reflected light and generates data about the cylinder surface.