A detection unit includes a first contact member that comes into contact with a surface of a recording material and a second contact member that comes into contact with the other surface of the recording material, and the first contact member and the second contact member face each other and are capable of nipping the recording material. The first contact member and the second contact member are movable in a direction in which the first contact member and the second contact member nip the recording material. The first contact member and the second contact member are rotatable about an axial line that extends in a direction in which the recording material is conveyed.

The invention relates to an online measurement system and method for multiple parameters of a wheel based on structured light. The measurement system comprises a wheel sensor, a first wheel online measurement device and a second wheel online measurement device, and is characterized in that both the first wheel online measurement device and the second wheel online measurement device comprise a tread structured light unit, a profile structured light unit and a two-dimensional image sensor. The tread structured light unit and the profile structured light unit project a profile contour curve and a tread contour curve on the wheel, the two-dimensional image sensor takes images, three-dimensional reconstruction is performed on the images to obtain tread contour information and profile contour information, and the wheel diameter, the wheel flange height and the wheel flange thickness are acquired according to the obtained contour information.

Evaluation of a rotating wheel is described. The evaluation utilizes information acquired by radiation reflecting off of one or more regions of the rotating wheel. An imaging device can acquire image data which is processed to evaluate the wheel. The radiation can comprise diffuse and/or coherent radiation. Image data for substantially an entire circumference of the wheel can be used in the evaluation.

A comprehensive information detection system for a steel wire rope, having a detection device, a stroke metering device, a data acquisition and conversion workstation, an alarm controller, and a terminal control master station is provided. The detection device further specifically has a steel wire rope electromagnetic detection device, a steel wire rope machine vision damage recognition device, a steel wire rope machine vision diameter measurement device, and a damage location marking device. The comprehensive information detection system for a steel wire rope may perform comprehensive evaluation on the damage situation of the steel wire rope and refine damage data information, thereby comprehensively improving the refinement degree of detection and the detection accuracy.

In order to optically sense a yarn moved in the longitudinal direction of the yarn, a yarn sensor has a light source, a detector and a light guiding element. The yarn sensor is based on the effect of frustrated total internal reflection (FTIR). Because of the FTIR effect, scattered light exiting the light guiding element in the contact region between the yarn and an outer surface of the light guiding element is detected by means of the detector, in which case sensing of the yarn lying against the outer surface is enabled. Alternatively, the reduced intensity in the totally internally reflected beam is then sensed by the detector. The intensity in the totally internally reflected beam is reduced mainly by the scattered light coupled out of the light guiding element.

Systems and methods are provided for determining attributes (such as size and location) of target objects (e.g., tires) utilizing photoelectric sensors. At least two photoelectric sensors are positioned at respective angles relative to a direction of transport of a conveyance mechanism such that the light rays emitted therefrom cross the width of the conveyance mechanism and cross one another at an intersection point. Based, at least in part, upon respective interruption times of the light rays by the target object, and a location of the interruption of the light rays relative to the intersection point, one or more attributes of the target object are determined. Systems and methods further are provided for determining a height profile of a target object utilizing at least one photoelectric sensor.

A displacement sensor for a frequency modulation continuous wave laser interference optical fiber, comprising a single mode frequency modulation continuous wave laser (1) and at least one optical fiber displacement sensing system; the optical fiber displacement sensing system comprises an optical circulator (2), an optical fiber collimator (3), a partial reflector (4), a cooperative reflector (5) and a photoelectric detector (6); the single mode frequency modulation continuous wave laser (1) is connected to an incident port of the optical circulator (2) by means of a single mode optical fiber or an optical fiber coupler; an adjacent emergent port of the optical circulator (2) is connected to the optical fiber collimator (3) by means of the single mode optical fiber; a third port of the optical circulator (2) is connected to the photoelectric detector (6).

Various embodiments provide an elongated part measuring apparatus including an elongated frame, an elongated transparent part supporter supported by the frame and configured to support an elongated part (such as a guide wire or mandrel), an elongated movable part straightener pivotally connected to and supported by the frame, and a movable optical measurer movably connected to and supported by the frame and configured to take multiple spaced apart outer dimensional measurements of the elongated part (whether uncoated or coated).

A pipe tally vision system may be positioned on a drilling rig. A drill string may be positioned within a wellbore using the drilling rig. The drill string may be observed with the pipe tally system during a wellbore operation. A pipe tally database may be generated by the pipe tally system based on the observations of the drill string made by the pipe tally system and observations may be made as the drill string is moved into or out of the wellbore.

An example automated locomotive spotting system includes a locomotive having a tractive effort mechanism for moving the locomotive along a track, and a locomotive controller configured to control the tractive effort mechanism to move the locomotive along the track. The locomotive controller includes an odometer configured to monitor a distance traversed by the locomotive along the track. The locomotive controller is configured to receive a requested spotting distance value, and initiate movement of the locomotive along the track via the tractive effort mechanism. The locomotive controller is also configured to monitor, by the odometer, the distance traversed by the locomotive along the track, and inhibit movement of the locomotive in response to the monitored odometer distance indicating the locomotive has traversed the requested spotting distance.