The invention relates to a luminaire element (10, 11) for an inspection tunnel (100), in particular for checking shiny surfaces, in particular painted surfaces, comprising at least two, preferably strip-like, arrangements (12) of light sources (13) in a luminaire housing (14) having at least two edge regions (15) lying opposite one another along a longitudinal extension (L) of the luminaire housing (14), wherein the strip-like arrangements (12) of the light sources (13) are formed along the longitudinal extension (L) at the edge regions (16), wherein a light exit surface (20) of the luminaire housing (14) has a higher radiation intensity along the edge regions (16) than in a central region (30). The invention further relates to a luminaire strip (50) having an arrangement of luminaire elements (10, 11) of this kind and to an inspection tunnel having an arrangement of a plurality of luminaire strips (50).

The present invention teaches an apparatus for consistent and accurate on-site readings of fluorescence signals of coronavirus test result, with which a user directly reads a fluorescent light qualitatively instead of using electronic sensors. The fluorescent light is excited from a fluorescent source in a site of interest in a target assay. The device comprises a light source for generating an excitation light for exciting the fluorescent source of the target assay to generate a fluorescent light, a component for accurately transmitting the excitation light and the fluorescent light with less noise or reflection, a component for consistent detecting of the fluorescent source by bare eyes with minimal health risks, and a user control system that requires minimal training.

A self-contained metrology wafer carrier systems and methods of measuring one or more characteristics of semiconductor wafers are provided. A wafer carrier system includes, for instance, a housing configured for transport within the automated material handling system, the housing having a support configured to support a semiconductor wafer in the housing, and a metrology system disposed within the housing, the metrology system operable to measure at least one characteristic of the wafer, the metrology system comprising a sensing unit and a computing unit operably connected to the sensing unit. Also provided are methods of measuring one or more characteristics of a semiconductor wafer within the wafer carrier systems of the present disclosure.

A kaleidoscopic display assembly, comprising: (a) a stand; (b) a kaleidoscope tube supported by the stand; (c) a display container in alignment with the kaleidoscope tube for containing at least a first botanical specimen viewable in a kaleidoscopic pattern through a viewing opening of the kaleidoscope tube; and (d) an aroma container positioned alongside the tube and enclosing an aroma chamber for containing a second botanical specimen. The aroma container has one or more scent ports extending therethrough for sampling an aroma of the second botanical specimen during viewing of the kaleidoscopic pattern.

The present invention relates to a method for, and wearing parts to be used in a method for, condition based preventive maintenance (PM) or predictive maintenance (Pd M) based on detecting excessive wear of a wearing part which wearing part either consists primarily of, or is covered at least partially by a sliding layer consisting primarily of, a polymer material and which wearing part comprises one or more optical fibers which in the proximal end is connected to a proximal light detecting device and in the distal to a distal end light detecting device.

A laminated fluorescent sensor includes a sealable sensor housing and an optical sensing system embedded inside the sealable sensor housing. The optical sensing system includes a light source (7), a short wave pass filter (8), an air chamber (10), a sensing unit, a long wave pass filter set (12) and an optical signal collecting unit from top to bottom all of which are coaxially set. The optical signal collecting unit is connected with a signal processing system (14); the sealable sensor housing has air inlets (2, 201) and an air pumping port (3), the air inlets (2, 201) are communicated with the air chamber (10) through an air intake passage, the air chamber (10) is communicated with the air pumping port (3) through an air pumping passage.

A device (10) for detecting the presence of at least one microorganism in the contents (101, 201) of a container (100, 200) comprising a wall with a translucent zone, said detection device (10) comprising: a) at least one light source (11), such as a light-emitting diode (LED), capable of illuminating the contents of the container (100, 200) by emitting an excitation light beam through the translucent zone of the container (100, 200); b) at least one detection means (12, 13, 14, 15), such as a photodiode, for detecting at least one reaction light beam emitted in response to the illumination of the contents (101, 201) of the container (100, 200);
said at least one light source (11) and said at least one detection means (12, 13, 14, 15) being equipped with at least one connection means (105, 205), to connect said at least one light source (11) and said at least one detection means (12, 13, 14, 15) to the wall of the container (100, 200), in the translucent zone, said at least one detection means (12, 13, 14, 15) being positioned at an angle of a set value in relation to the direction of the excitation light beam, to detect the reaction light beam.

Provided herein is a dust measuring apparatus. The dust measuring apparatus includes: a body; a window unit exposed to the outside through an opening part of the body, such that dust present in the outside is gathered on the window unit; a light emitting unit emitting light to the window unit; a light receiving unit receiving light reflected from the window unit; and a controlling unit measuring an amount of dust gathered on the window unit on the basis of strength of the emitted light and strength of the received light.

A MEMS gas sensor includes a photoacoustic sensor including a thermal emitter and an acoustic transducer, the thermal emitter and the acoustic transducer being inside a mutual measurement cavity. The thermal emitter includes a semiconductor substrate and a heating structure supported by the semiconductor substrate. The heating structure includes a heating element. The MEMS gas sensor further includes a chemical sensor thermally coupled to the heating element, and the chemical sensor including a gas adsorbing layer.

A device for holding and testing plant material includes a sample container including a sample fixation member for affixing thereto a plant sample such that the plant sample is held vertically in the sample container, a test and calibration reference, a spectrometer arranged to perform spectrometric analysis of the plant sample with respect to spectrometric analysis of the test and calibration reference, and a multiple-degree-of-freedom positioning device configured to cause relative movement between the sample container and the spectrometer.