Abstract: A sorting apparatus for sorting workpieces of a workpiece sheet includes a support region with support elements for placing the workpiece sheet thereon. At least one sorting opening for the workpieces to fall through is formed between adjacent support elements. The sorting apparatus further includes a collection region arranged below the support region and having at least two collection compartments for collecting the workpieces, a guide region arranged between the support region and the collection region and having at least one guide element for guiding the workpieces falling through the at least one sorting opening to the collection compartments, and an adjustment device for adjusting the collection compartments relative to the at least one guide element and/or for adjusting the at least one guide element relative to the collection compartments such that, via the at least one guide element, workpieces are selectively fed to a respective collection compartment.

Abstract: A laser cutting process for cutting at least one workpiece out of a metal sheet while leaving a residual part is provided. The process includes arranging the metal sheet on a support of a laser cutting machine, introducing at least one cutting line for separating the at least one workpiece from the residual part using the laser cutting machine, and introducing at least one separating line into the residual part using the laser cutting machine. In a main region of the separating line, the residual part is cut through. In a connecting region of the separating line, at least one joint remains between mutually adjacent portions of the residual part. The joint has a height that is smaller than a thickness of the metal sheet. The process further includes removing the residual part from the support, and separating the portions of the residual part from one another.

Abstract: A method for cutting at least one workpiece from a metal sheet includes arranging a metal sheet on a support of a laser cutting machine, and directing a laser beam onto the metal sheet along an outline of the workpiece. The metal sheet is cut through in a main region of the outline. At least one connecting portion, which has a height that is less than a thickness of the metal sheet, remains in at least one connection region of the outline between the workpiece and an adjoining part of the metal sheet. The method further includes removing the at least one workpiece and the adjoining part connected thereto from the support, and separating the at least one workpiece from the adjoining part.

Abstract: In a method for laser fusion cutting in particular a plate-shaped workpiece, preferably with a thickness D of at least 1 mm, a laser beam and a cutting gas, in particular nitrogen, at a cutting gas pressure are directed at the workpiece surface by a convergent cutting nozzle. The laser power is at least 6 kW and the cutting nozzle has a nozzle end face on the workpiece side. A distance A between the nozzle end face and the workpiece surface during the cutting operation is 2 to 8 mm. The cutting nozzle has a nozzle channel with a diameter dD at the nozzle end face on the workpiece side of 1.5 to 4 mm. The cutting gas pressure before emergence from the cutting nozzle is 15 to 30 bar. This makes it possible to achieve high productivity along with a reduced risk of collision, i.e. higher process reliability.

Abstract: A method for determining a minimum width of a microjoint by which, when machining a workpiece, in particular a sheet-like workpiece, a workpiece part remains connected to a remaining workpiece of the workpiece. In the method, the minimum width of the microjoint is determined in dependence on at least one machining parameter which influences a relative position of the workpiece part in relation to the remaining workpiece during the machining of the workpiece. A further method determines an attachment position of such a microjoint and a still further method machines the workpiece.

Abstract: A method for cutting machining of a plate-shaped workpiece, including determining the position of the support points either by measuring or inferring the position of the support points and/or the relative position of the workpiece, establishing starting-point-free regions, establishing end-point-free regions, establishing starting-point-free and end-point-free regions depending on the inferred or measured position of the support points and/or the relative position of the workpiece, establishing a grid of possible starting points and end points, omitting the starting-point-free and end-point-free regions determined in advance, either calculating a torque in a stabilizing and/or tilting direction or calculating a tilt height and/or a tilt depth for each of the points on the grid, setting a priority of points on the grid, transmitting the priority of points to a route planning means of the cutting head, and selecting one of the points on the grid and carrying out the cutting machining.

Abstract: Method for cutting a planar and/or metal workpiece along a predefined cutting contour using a laser beam and a cutting gas emitted from a nozzle, wherein the laser beam makes a recess in the workpiece so as to form a recess hole (on the cutting contour or at least partly close to the cutting contour. At least two machining parameters are continuously modified during formation of the recess hole, and/or at least one machining parameter is continuously modified on a switch path between the recess hole and an endpoint lying on the cutting contour.

Abstract: Methods and systems are implemented for forming a through hole in a workpiece using a laser beam and a process gas, such as oxygen or nitrogen, coming from a gas nozzle. A hole is formed in the workpiece using the laser beam and a process gas emerging from a gas nozzle, such that the formed hole extends only partially through the workpiece. A bulge deposited while forming the hole partially through the workpiece is removed from the workpiece surface by directing a flow of gas through the nozzle toward the workpiece surface as the nozzle is moved with the laser beam switched off, the flow of gas being delivered to the nozzle at a higher pressure than the process gas is delivered to the nozzle during forming the hole partially through the workpiece. Then, the hole is fully pierced through the workpiece by the laser beam using the process gas.

Abstract: Methods and systems are implemented for forming a through hole in a workpiece using a laser beam and a process gas, such as oxygen or nitrogen, coming from a gas nozzle. A hole is formed in the workpiece using the laser beam and a process gas emerging from a gas nozzle, such that the formed hole extends only partially through the workpiece. A bulge deposited while forming the hole partially through the workpiece is removed from the workpiece surface by directing a flow of gas through the nozzle toward the workpiece surface as the nozzle is moved with the laser beam switched off, the flow of gas being delivered to the nozzle at a higher pressure than the process gas is delivered to the nozzle during forming the hole partially through the workpiece. Then, the hole is fully pierced through the workpiece by the laser beam using the process gas.

Abstract: Detection systems and methods for detecting target biological analytes within sample material using acousto-mechanical energy generated by a sensor are disclosed. The acousto-mechanical energy may be provided using an acousto-mechanical sensor, e.g., a surface acoustic wave sensor such as, e.g., a shear horizontal surface acoustic wave sensor (e.g., a LSH-SAW sensor). A variety of techniques for modifying the effective mass of the target biological analytes in sample material are disclosed, including fractionating or disassembling the target biological analytes in the sample material (e.g., lysing the target biological analyte), adding a detectable mass to the target biological analyte or enhancing coupling of the target biological analyte (e.g., through the use of magnetic particles), exposing the sample material to a reagent that causes a change in at least detectable physical property in the sample material if the target biological analyte is present (e.g.

Abstract: The invention relates to methods of detecting staphylococcus.

Abstract: The invention relates to methods of enhancing signal detection of components of cell walls, wherein the methods involve lysing cells to form cell-wall fragments and analyzing the cell-wall fragments.