Abstract: An optochemical sensing device has source that emits radiation of a first and a second predetermined intensity, a detector, and a sensitive element that comprises a signal substance. To measure an analyte in a measurement medium, the sensitive element is contacted with the analyte. A first raw signal, which is dependent on the analyte content is obtained by exciting the signal substance with radiation of the first predetermined intensity. At a later time, a second raw signal is also obtained. A comparison of the raw signals yields a comparison value, which is compared against a predetermined limit value. If the comparison value exceeds the limit value, the radiation source is set at the first intensity. If the comparison value is smaller than the limit value, the radiation source is set at the lower second intensity. Using the lower radiation intensity prolongs the life of the sensitive element.

Abstract: A weighing cell based on the principle of electromagnetic force compensation and having an optoelectronic position sensor that includes a light source, a light receiver, and a shutter vane. The light receiver functions to generate a position sensor signal corresponding to a deflection of the shutter vane from a zero position which occurs as a result of placing a load onto a load receiver of the weighing cell. A controller functions to regulate compensation current in response to the position sensor signal in such a way that the shutter vane and the movable parts of the weighing cell connected to the shutter vane are returned to the zero position by the electromagnetic force between a coil and permanent magnet system of the weighing cell.

Abstract: A device that dispense dosages of a free-flowing substance has a support column with a horizontal support arm (10) cantilevered thereon. The device includes a holder unit (20) on which at least one movably supported receiving unit (30) is arranged. The receiving unit is designed so that at least one dosage unit (70) can be set into, as well as taken out of, it. The holder unit contains at least one agitation actuator (50) that acts on the receiving unit. The dosage unit can be fastened to the receiving unit by means of a pre-tensioned clamping module (60). For the insertion and/or removal of the dosage unit, the clamping module can be spread apart from a dispensing position into a loading position by means of an opener module that is based on the holder unit. In the dispensing position, the opener module is uncoupled from the receiving unit.

Abstract: A parallel-guiding mechanism (120) has a movable parallel leg (121), a stationary parallel leg (122), a first parallel-guiding member (123) and a second parallel-guiding member (124). The parallel legs and the parallel-guiding members are connected to each other by flexure pivots, in the form of narrow material connections. There is at least one adjustment zone (135). An adjustment flexure fulcrum (136) is arranged between a flexure pivot (131) and a parallel leg. The adjustment zone is connected to the first lever end (138) of an adjustment lever (137). The adjustment flexure fulcrum forms the lever fulcrum (146) of the adjustment lever, which has an elastic domain with a section modulus that is smaller than a section modulus of the adjustment flexure fulcrum.

Abstract: A weighing cell based on the principle of electromagnetic force compensation. A permanent magnet system is mounted on a base part and includes an air gap within which is suspended a coil that is connected to a load receiver through a force-transmitting mechanism. The coil carries an electrical compensation current when the weighing cell is in operation. An optoelectronic position sensor is also included, and its signal corresponds to the deflection of the coil from a zero position which occurs as a result of placing a load on the load receiver. A closed-loop controller regulates the compensation current in response to the sensor signal in such a way that the coil and the load receiver that is connected to it are returned to their zero position by the electromagnetic force that is acting between the coil and the permanent magnet.

Abstract: An instrument (10) for gravimetrically determining moisture content has a housing (20), with a weighing device (40) arranged inside. The weighing device (40) has a load receiver (60) onto which a sample (62) is placed. The housing has a stationary housing part (21) and a movable housing part (22), the movable housing part alternately occupying a measuring position and a loading position. In the loading position, the respective housing parts are spaced apart from each other, allowing a sample to be put on the load receiver. In the measuring position, the respective housing parts form an essentially enclosed testing compartment (30) that surrounds the load receiver. A means (70), arranged in the testing compartment, heats a sample that is placed on the load receiver. The movable housing part is moved between the respective positions by a position-changing device.

Abstract: An instrument (10) for gravimetrically determining moisture content has a housing (20), with a weighing device (40) arranged inside. The weighing device (40) has a load receiver (60) onto which a sample (62) is placed. The housing has a lower, stationary housing part (21) and an upper, movable housing part (22), the movable housing part alternately occupying a measuring position and a loading position. In the loading position, the respective housing parts are spaced apart from each other, allowing a sample to be put on the load receiver. In the measuring position, the respective housing parts form an essentially enclosed testing compartment (30) that surrounds the load receiver. A temperature sensor (80) is arranged so that the temperature sensor is above the load receiver in the measuring position and is essentially to the side of the load receiver in the loading position.

Abstract: An instrument (10) for gravimetric moisture determination has a housing (20) and a weighing device (40) arranged inside. The weighing device has a load receiver (60) onto which a sample (62) is placed. The housing has stationary (21) and movable (22) housing parts, the movable housing part alternately occupying a measuring and a loading position. wherein in the loading position the stationary housing part and the movable housing part are spaced apart from each other in such a way that a the sample can be put on the load receiver, wherein in the measuring position the respective housing parts form an essentially enclosed testing compartment (30) surrounding the load receiver (60), and wherein a sample-heating means (70) is arranged in the testing compartment to heat the sample on the load receiver. The instrument also has an electrical contact means (85) with first (86) and second parts (87).

Abstract: An instrument (210) for gravimetrically determining moisture content has a housing (220), with a weighing device (40) arranged inside. The weighing device (40) has a load receiver (260) onto which a sample (62) is placed. The housing has stationary and movable housing parts (221,222), the movable housing part moving between a measuring position and a servicing position. In the measuring position, the respective housing parts form an essentially enclosed testing compartment (30) surrounding a load receiver (260) in which a sample heater (270) heats a sample. In the servicing position, the respective housing parts are spaced apart from each other, allowing the sample heater to be accessed for servicing. A glass shield (272), protects the sample heater while in the measuring position. The glass shield is arranged on the movable housing part and can be taken out without using tools when in the servicing position.

Abstract: An sampling device for capturing a material sample and a method of using said device to process said material sample in situ within the device. Embodiments of the invention may be disposed as elongate probes having extendable sample capture elements. A sample capture element of such a device may include a sample capture pocket located near a distal end thereof for capturing and trapping a sample of material. The sample capture pocket may be provided with a port for receiving material therein and a port for expelling material therefrom. These ports may be placed in communication with corresponding material transfer channels extending through the sample capture element to allow for the in situ processing of a material sample, and the subsequent discharge of the sample to an analyzer or another downstream location.

Abstract: A check weight (1) that is used to check a gravimetric measuring instrument, specifically a balance, or to check a further weight, is provided with a means of identification. This marking which is applied on the outside surface of the check weight includes a permanently affixed machine-readable identification code (2) which makes the specific weight piece individually recognizable. This opens the possibility for a method whereby an individually identifiable check weight can be traced back in time. A system for tracing check weights back in time includes one or more reader devices (6) that serve to record the marking, one or more processors (10) wherein the machine-readable identification code can be converted back into an identification code that can be electronically processed, and one or more data storage units, in particular a database (8) serving to store at least the data contained in the identification code.