Measuring device (1) for measuring the length of sealing profiles (2) in a sealing profile application device, comprising a measuring belt (4). The measuring belt runs over at least two rollers (3a, 3b). The measuring belt (4) and/or at least one of the rollers (3a, 3b) interacts with a measured value acquisition system (5), a transport fixture (6) with a conveyor belt (7) running over rollers (3a, 3b) being arranged opposite the measuring belt (4). The measuring device (1) is arranged in an application head (8) of the sealing profile application device’. Also, a measuring belt contact area (KM) of the sealing profile (2) with the measuring belt (4) extends longer than a transport contact area (KT) of the sealing profile (2) with the conveyor belt (7).

A specimen machining device includes an illumination system that illuminates a specimen; a camera that photographs the specimen; and a processing unit that controls the illumination system and the camera, and acquires a machining control image which is used for controlling an ion source and a display image which is displayed on a display unit. The processing unit controls the illumination system to illuminate the specimen under a machining illumination condition; acquires the machining control image by controlling the camera to photograph the specimen illuminated under the machining control illumination condition; controls the ion source based on the machining control image; controls the illumination system to illuminate the specimen under a display illumination condition which is different from the machining control illumination condition; acquires the display image by controlling the camera to photograph the specimen illuminated under the display illumination condition; and displays the display image on the display unit.

A specimen machining device includes an illumination system that illuminates a specimen; a camera that photographs the specimen; and a processing unit that controls the illumination system and the camera, and acquires a machining control image which is used for controlling an ion source and a display image which is displayed on a display unit. The processing unit controls the illumination system to illuminate the specimen under a machining illumination condition; acquires the machining control image by controlling the camera to photograph the specimen illuminated under the machining control illumination condition; controls the ion source based on the machining control image; controls the illumination system to illuminate the specimen under a display illumination condition which is different from the machining control illumination condition; acquires the display image by controlling the camera to photograph the specimen illuminated under the display illumination condition; and displays the display image on the display unit.

A method and a device are described for measuring structural components of a bearing structure of an escalator or moving walkway without specialized personnel having to carry out precise measurements in situ. The method comprises fixing an image recording device on a conveying means of the escalator, removing at least one of the tread units of the escalator in order to enable visual access to structural components beneath it; moving the conveying means together with the image recording device at least over partial areas of a travel path, recording images of the structural components to be measured with the image recording device, and generating a 3D model of at least a partial area of the structural components of the bearing structure based on the recorded images. Using the 3D model experts can then measure dimensions and spatial arrangements of structural components without having to be in person at the actual location.

A method and a device are described for measuring structural components of a bearing structure of an escalator or moving walkway without specialized personnel having to carry out precise measurements in situ. The method comprises fixing an image recording device on a conveying means of the escalator, removing at least one of the tread units of the escalator in order to enable visual access to structural components beneath it; moving the conveying means together with the image recording device at least over partial areas of a travel path, recording images of the structural components to be measured with the image recording device, and generating a 3D model of at least a partial area of the structural components of the bearing structure based on the recorded images. Using the 3D model experts can then measure dimensions and spatial arrangements of structural components without having to be in person at the actual location.

A device for determining the length of a vehicle combination comprises an input interface for receiving current driving dynamics data, in particular information regarding the current travel path of the towing vehicle, and a comparison unit for comparing the received current driving dynamics data with stored patterns of driving dynamics data that are typical for driving with a trailer of known dimensions, and an evaluation unit, which derives the length of the vehicle combination from the differences between the current driving dynamics data and the stored typical patterns of driving dynamics data. The device can use the sensors in the towing vehicle for obtaining the current driving dynamics data. Without additional hardware, a length of the vehicle combination, e.g. the length of a trailer connected to a towing vehicle, can be determined in this manner.

The invention relates to a handling device and/or layer forming device (10) and a method for forming piece good layers. Piece goods (14, 14a) are conveyed on a horizontal conveying device (16) to a grouping station and/or layer forming station (12) comprising a manipulator (20). In a work cycle the manipulator (20) seizes at least one piece good (14, 14a) and moves it into a defined relative target position and/or target alignment, in particular with regard to a piece good layer to be formed.

The horizontal conveying device (16), which is arranged upstream of the grouping station and/or layer forming station (12) in the transport direction (18) of the piece goods (14, 14a), comprises at least one sensor device (24) for obtaining positional data and/or dimensional data and/or alignment data of the transported piece goods (14, 14a). Electronic output signals (26) are generated from the obtained data, which processed in a control device (28). The control device (28) controls the movements of the manipulator (20) within the movement range (22) for the purpose of the layer formation.

A method for determining the length of a line involves determining a length of a first electrical line, determining an identifier of the first electrical line, determining a length of a second electrical line, which is intended for installation in an electrical installation assembly, based on the length of the first electrical line and a starting length determined by means of the identifier.

A screw length determination system capable of quickly determining the length of a screw is obtained. A PLC (10) is equipped with a determination part for measuring the moving speed of a driver for tightening screws in the axial direction of the driver from an initial position until a screw contacts and is screwed into a workpiece, and determining the length of the screw on the basis of the time from the start of movement from the initial position until the moving speed changes.

A screw length determination system capable of quickly determining the length of a screw is obtained. A PLC (10) is equipped with a determination part for measuring the moving speed of a driver for tightening screws in the axial direction of the driver from an initial position until a screw contacts and is screwed into a workpiece, and determining the length of the screw on the basis of the time from the start of movement from the initial position until the moving speed changes.