An optical water quality sensor includes a holder base having a first light-transmitting portion and a second light-transmitting portion extending in the same direction, a first receiving groove and a second receiving groove respectively extending into the first light-transmitting portion and the second light-transmitting portion and a first light-condensing side and a second light-condensing side respectively located on the inner sides of the first light-transmitting portion and the second light-transmitting portion, and a sensor module with a circuit board assembled in the accommodating space. The circuit board has a first arm plate and a second arm plate respectively inserted into the first receiving groove and the second receiving groove, and a light emitter and a light receiver respectively located on the first arm plate and the second arm plate to face the first light-condensing side and the second light-condensing side.

The application is directed to a device housing. The device housing includes a first light device, the first light device including a first electrical supply configured to provide an electrical signal to a first light emitting diode (LED), the first LED separated from a first surface of a diffuser film by a space, wherein the diffuser film includes a second surface, opposite the first surface, the second surface configured to contact a first light pipe.

A laser analysis device includes a laser analysis unit that a sample is irradiated with laser light, a cover that covers a periphery of the laser analysis unit, so as to prevent the laser light from being emitted to outside, and has a slit in at least a part of the cover, a fastener configured to open and close the slit, and an interlock mechanism including a key provided on the fastener and a detector that detects a state in which the fastener is fully closed, in which in a state where the detector has detected that the fastener is fully closed, laser light having a predetermined intensity or more is introduced into the laser analysis unit.

A refrigerant detection assembly operable to detect refrigerant mixed with air includes a housing having an internal cavity fluidly connected with an ambient atmosphere surrounding the housing via an opening. A subassembly mounted within the internal cavity includes an air chamber fluidly connected with the internal cavity, a non-dispersive infrared sensor operably coupled to the air chamber, a printed circuit board, and a heat conduction plate mechanically and thermally coupled to the printed circuit board. At least one insulator is arranged within the internal cavity at a position between a portion of the subassembly and the housing. A shell is connectable to the housing in overlapping arrangement with the opening. The shell has at least one shell opening formed therein such that a flow path extends from the shell opening, through the opening formed in the housing to the internal cavity, and into the air chamber.

A detection device according to an aspect of the present disclosure includes a detection portion that contains a substance that emits fluorescence in a case of being irradiated with light when reacting with a plant hormone.

A refrigerant detection assembly operable to detect refrigerant mixed with air includes a housing having an internal cavity fluidly connected with an ambient atmosphere surrounding the housing via at least one opening and a sensor subassembly mounted within the internal cavity. The sensor subassembly includes a sensor, a printed circuit board, a heat preservation housing mechanically and thermally coupled to the printed circuit board, and at least one shielding component mechanically coupled to the printed circuit board.

A luminometer (400) includes a light detector (630) configured to sense photons (135). The luminometer (400) includes an analog circuit (915a) configured to provide an analog signal (965) based on the photons (135) emitted from assay reactions over a time period and a counter circuit (915b) configured to provide a photon count (970) based on the photons (135) emitted from the assay reactions over the time period. The luminometer (400) includes a luminometer controller (905) configured to, in response to an analog signal value of the analog signal (965) being greater than a predetermined value, determine and report a measurement value of the photons (135) emitted from the assay reactions over the time period based on the analog signal value of the analog signal (965) and a linear function (1010). Optionally, the linear function (1010) is derived from a relationship between the analog signal (965) and the photon count (970).

A gas detector is provided and includes a gas detector element, electronics to interface with the gas detector element and an enclosure configured to expose the gas detector element to an exterior and to form an electronics housing area in which the electronics are disposed whereby the electronics are isolated from the exterior.

An industrial X-ray imaging apparatus including: an X-ray source; an X-ray detector configured to detect X-rays emitted from the X-ray source; a stage which is disposed between the X-ray source and the X-ray detector and is configured to support a subject; and a shielding chamber configured to accommodate the X-ray source, the X-ray detector, and the stage, in which the shielding chamber includes a door for carrying in and out the subject, and a lock mechanism for prohibiting the door from changing to an open state, and in which the X-ray imaging apparatus further includes an unlocking control unit configured to control unlocking of the lock mechanism based on a leakage dose leaking from the shielding chamber to an outside.

Provided are a diffusion plate that diffuses light emitted from a light source, and a prism having a first surface to receive the light transmitted through the diffusion plate, a second surface to reflect the light in contact with a measurement target liquid, and a third surface to extract the reflected light. The light source, the diffusion plate, a light receiving lens, and an imaging element are accommodated in a holder that presses the prism from the inner side to the outer side.