An integral system for automated and non-intrusive of cleaning and non-destructive inspection (ultrasonic volumetric testing and visual testing) to detect, characterize and monitor with precision the level of internal and external damage (Cracks, deformations, corrosion, erosion, etc.) that may be present in coke drums throughout their life cycle is disclosed. Embodiments are disclosed that enable a condition of a coke drum to be estimated in a reliable manner for their fitness for service from the results obtained from the automated inspection with the non-destructive methods of ultrasound and visual testing.

A laser gas detection system includes a laser gas detector and a near-eye display device. The laser gas detection system provided in the present disclosure incorporates modern display technologies and modern communication facilities to present detection results to a user of the laser gas detection system in various intuitive and highly readable forms. The laser gas detection system is further capable of projecting the detection results to a field of view of the user through the near-eye display device.

A laser gas detection system includes a laser gas detector and a near-eye display device. The laser gas detection system provided in the present disclosure incorporates modern display technologies and modern communication facilities to present detection results to a user of the laser gas detection system in various intuitive and highly readable forms. The laser gas detection system is further capable of projecting the detection results to a field of view of the user through the near-eye display device.

A data management terminal for a laser gas detector, and a data management method thereof are provided. The data management method includes: the data management terminal establishes a connection to a communication port of the laser gas detector, and obtains target gas concentration data in a target region through the connection; the data management terminal creates a target gas concentration log according to the target gas concentration data; and the data management terminal transmits the target gas concentration log to a server.

A borescope includes a housing extending from a first end toward a second end, the housing including a first transparent viewing section extending circumferentially around a longitudinal axis of the housing and defining an exterior of a portion of the housing; a first imaging assembly configured to rotate about the longitudinal axis of the housing, and also pivot relative to the longitudinal axis of the housing; and a second imaging assembly disposed within the housing, the second imaging assembly being configured to rotate about the longitudinal axis of the housing, wherein the second imaging assembly is configured to visualize a field of view exterior of the housing through the first transparent viewing section.

The present disclosure discloses a mechanism for aligning and orienting a probe in an optical system. The mechanism includes a sensor head, which are defined with one or more provisions. Further, the mechanism includes at least one block member, which is movably disposed within the one or more provisions in the sensor head. The at least one block member is defined with a cavity to accommodate a probe. During contact of the probe with a surface of the subject, a torque is generated, which facilitates in aligning the probe on the surface of the subject. The block member is configured to tilt corresponding to movement of the probe, for aligning the probe at an angle on the surface of the subject.

A borescope includes a housing extending from a first end toward a second end, the housing including a first transparent viewing section extending circumferentially around a longitudinal axis of the housing and defining an exterior of a portion of the housing; a first imaging assembly configured to rotate about the longitudinal axis of the housing, and also pivot relative to the longitudinal axis of the housing; and a second imaging assembly disposed within the housing, the second imaging assembly being configured to rotate about the longitudinal axis of the housing, wherein the second imaging assembly is configured to visualize a field of view exterior of the housing through the first transparent viewing section.

The present disclosure relates to a system for process-integrated optical analysis of flowable media, comprising a processing system for processing a flowable medium and an analytical system for analysis of the flowable medium, wherein the analytical system includes an optical measuring head, for irradiation of the medium and for receiving measuring radiation, and a reference unit. The processing system includes a measuring region, into which the medium can be introduced during the processing and which is accessible for measurement by means of the measuring head. According to the invention, a mechanism for achieving defined positions of the measuring head relative to the measuring region and/or relative to a reference unit is included, which selectively enables a measurement of the medium located in the measuring region or of the reference unit.

A spectroscopic measurement device emits light to a measurement target and measures the measurement light output from the measurement target in accordance with the light emission. A spectroscopic measurement device includes: a first housing having a light shielding property and configured to house a light source that emits light and having a first opening through which the light emitted from the light source passes; a second housing having a light shielding property and having a second opening through which the measurement light passes and configured to house a spectrometer that receives the measurement light that has passed through the second opening; and an arm member configured to relatively rotatably join the first housing and the second housing. A proximal end side of the arm member is rotatably joined with the second housing. The first housing is attached to a distal end side of the arm member.

A portable lighting device has an upright configuration and a folded configuration. In the upright configuration, the portable lighting device provides lighting directed to a workspace area. In the folded configuration, the legs of the portable lighting device are rotated into a compact position for transport or storage. The portable lighting device includes lugs to hold one or more objects, which helps increase the surface area of the workspace. The portable lighting device is suitable for different uses of tradespersons and hobbyists. For example, a user can use the portable lighting device while working on radio-controlled car or electrical or hardware repairs.