A lock monitoring device includes a detection unit and a plurality of sensors, where the detection unit is configured with a thin circuit board configured with a plurality of detection elements, allowing the detection elements to be connected in parallel with a circuit and then connected to a control circuit; the sensors are configured on parts of the lock such as lock tongues, rotating shaft and correspond to the detection elements; whereby, when the lock is unlocked and locked, the detection elements will detect that the detection elements depart from detection positions and send detection signals to a remote monitoring host, and the monitoring host monitors and records the number and time of the unlocking of the lock, achieving smart access control and further allowing the lock to be safer.

A rotary position detector includes a housing having an inner space having a reflective element. A light source emits light rays into the inner space. A base supports a light detector assembly having a first number of toroidal-sector-shaped light sensors arranged circumferentially about a motor shaft axis, is, one “Cosine +” detector element, one “Cosine −” detector element, one “Sine +” detector element, and one “Sine −” detector element. A light blocker positioned between the light source and the light sensors rotates with the shaft. The light blocker includes a second number of opaque, equal-surface-area elements arrayed about the axis, the second number equal to one-half the first number. A circuit measures a signal from the detectors relating to an amount of light falling thereon, a difference related to an angular position of the motor shaft.

A braking device of a fishing reel comprises: a braked part made of a conductor, the braked part being attached to a spool designed to wind a fishing line; a braking part generating braking force by providing a magnetic field for the braked part; a part being detected that is provided on the braked part; and a rotation detection sensor sensing rotation of the spool by detecting the part being detected.

A larvae counter comprising a first container for receiving water, eggs of insects and/or larvae, a second container in fluid communication with the first container for receiving water and larvae from the first container, and a larvae counting module in fluid communication with the second container for receiving water and larvae from the second container and counting the larvae.

A rotary encoder for a valve comprises a rotatable code plate and an optical detector module comprising one or more optical detectors. The code plate defines a set of voids arranged along a set of one or more concentric circular arcs about an axis of rotation. The voids define an angle-dependent pattern over the set of arcs, the pattern comprising a plurality of distinct sectoral elements (A-O, X). At least two of the sectoral elements, located in non-adjacent sectors of the code plate, are identical, but the pattern is non-repeating over a single full rotation of the code plate about the axis. Each optical detector is aligned with a respective concentric circular arc of the code plate. A controller processes time-varying output signals from the optical detectors to determine successive positions of the rotatable code plate.

An optical system may include a light source to provide a beam of light. The optical system may include a reflector to receive and redirect the beam of light. The optical system may include a light gate having an opening to permit the beam of light, from the reflector, to travel through the opening. The optical system may include a light sensor to receive a portion of the beam of light after the beam of light travels through the opening, and convert the portion of the beam of light to a signal. The optical system may include a processing device to determine whether a notch of a wafer is in an allowable position based on the signal.

A dispensing system (2) and method for dispensing unit dosage forms (38) from a blister pack (30) is disclosed. The system (2) comprises a housing (4) for receiving a blister pack (30), the blister pack (30) having a plurality of cavities (32) with at least one unit dosage form (38) sealed in each of the cavities (32), the housing (4) comprising at least one housing aperture. The system (2) also comprises a sensing layer comprising a plurality of apertures, each sensing layer aperture configured to substantially align with a corresponding one or more of the plurality of cavities (32) of the blister pack (30) when a blister pack (30) is received in the housing (4) and at least one sensing region. The system (2) further comprises an electronics unit and a power source for providing voltage to the sensing layer. In use, the unit dosage forms (38) are dispensed from the blister pack (30) through the sensing layer apertures and through the at least one housing aperture, for example by application of pressure (P) upon each cavity (32), and the sensing layer senses each unit dosage form (38) being dispensed from the blister pack (30).

In this boom slewing angle detection device, a slewing angle detecting gear is attached to an end of a shaft of a pinion gear that meshes with a ring gear formed on a slewing bearing rotatably supporting a crane boom, and the amount of rotation of the slewing angle detecting gear is detected by a slewing-angle-detecting proximity sensor. The slewing angle detecting gear is not meshed with the ring gear or the pinion gear, which compose a slewing force transmission mechanism; thus, grease, and the like, do not adhere to the slewing angle detecting gear, and external teeth for detection of the slewing angle detecting gear are not subject to wear, so accurate slewing angle detection is possible.

A system is provided with a measurement system having a light source, a light sensor, and a controller coupled to the light source and the light sensor. The controller is configured to determine a clearance between a rotor and a casing at least partially based on an interruption of light transmitted from the light source to the light sensor.

A lock monitoring device includes a detection unit and a plurality of sensors, where the detection unit is configured with a thin circuit board configured with a plurality of detection elements, allowing the detection elements to be connected in parallel with a circuit and then connected to a control circuit; the sensors are configured on parts of the lock such as lock tongues, rotating shaft and correspond to the detection elements; whereby, when the lock is unlocked and locked, the detection elements will detect that the detection elements depart from detection positions and send detection signals to a remote monitoring host, and the monitoring host monitors and records the number and time of the unlocking of the lock, achieving smart access control and further allowing the lock to be safer.