Abstract: An offshore wind turbine floating on a water surface with a rotor with a shaft rotatable about a vertical axis of rotation, the shaft being connected to a generator which converts a rotational movement of the shaft into electrical energy, and with at least one floating body.

Abstract: A method for calibrating an optical arrangement in respect to a global coordinate system is provided. The optical arrangement includes a rigid carrier, an optical acquiring unit and a light emitting unit both releasably connected to the carrier. The optical acquiring unit or the light emitting unit is calibrated in respect to a reference coordinate system offline and independently from the optical arrangement. Values of a conversion matrix are determined for converting the calibration data into corresponding calibration data in respect to the global coordinate system. A calibration of the entire optical arrangement is performed once in respect to the global coordinate system. During the intended use of the optical arrangement, the calibration data acquired for the unit and/or the respective values of the conversion matrix are considered when generating control signals for the unit and/or when processing sensor signals received from the unit.

Abstract: The invention refers to a method for in-line calibration of an industrial robot (1). The robot (1) comprises a fixed base section (2) and a multi chain link robot arm (3). The chain links (4) are interconnected and connected to the base section (2) of the robot (1), respectively, by means of articulated joints (5). An end effector (6) of the robot arm (3) can be moved in respect to the base section (2) within a three-dimensional workspace into any desired location. The idea is to move the end effector (6) into a predefined calibration location and to determine characteristic parameters of the robot (1) for that location. The characteristic parameters are compared to previously acquired values of the corresponding parameters for that calibration location.

Abstract: A method for calibrating an optical arrangement in respect to a global coordinate system is provided. The optical arrangement includes a rigid carrier, an optical acquiring unit and a light emitting unit both releasably connected to the carrier. The optical acquiring unit or the light emitting unit is calibrated in respect to a reference coordinate system offline and independently from the optical arrangement. Values of a conversion matrix are determined for converting the calibration data into corresponding calibration data in respect to the global coordinate system. A calibration of the entire optical arrangement is performed once in respect to the global coordinate system. During the intended use of the optical arrangement, the calibration data acquired for the unit and/or the respective values of the conversion matrix are considered when generating control signals for the unit and/or when processing sensor signals received from the unit.

Abstract: The invention relates to a method and a device for the quality control of a rotationally symmetrical body (2, 2, 2?) and a grip (4) of a handling system (5) for gripping a rotationally symmetrical body (2, 2, 2?). The aim of the invention is to improve the quality control of rotationally symmetrical bodies (2, 2, 2?) in such a way that it is faster, reliable and more economical. To this end, the grip (4) comprises grip fingers (26) having rotationally symmetrically holding elements (29, 31) for holding the body (2, 2, 2?), the holding elements (31) being mounted in the grip fingers (26) in such a way that they can be rotated about the rotational axes (29) thereof. In order to grip the body (2, 2, 2?), the grip fingers (26) are displaced on a circular path. A central drive mechanism (22; 35) is respectively provided for the rotational movement of the holding elements (29, 31) of all of the grip fingers and for the rotational movement of all of the grip fingers (26).

Abstract: The invention refers to a Method (69) for automatically inserting at least one part (13) into a storage section (15) of a container (11), wherein the storage section (15) comprises a plurality of holder means (17a-d), wherein the part (13) is inserted (103) by means of an insertion tool (49), and wherein the method (69) comprises the step of detecting (93) the position of the holder means (17a-d) by means of at least one optical sensor (51a-d). In order to provide a method for automatically inserting a part into a storage section (15), wherein collisions are avoided it is suggested that the method (69) further comprises the steps of verifying (95) whether the holder means (17a-d) of a certain storage section (15) are available for insertion of the part (13); detecting (99) the orientation of the holder means (17a-d); determining (100) an insertion path (47) along which the part is inserted; and inserting (103) the part (13) into the available storage section (15) along the determined insertion path (47).

Abstract: The invention relates to a method and a device for the quality control of a rotationally symmetrical body (2, 2, 2?) and a grip (4) of a handling system (5) for gripping a rotationally symmetrical body (2, 2, 2?). The aim of the invention is to improve the quality control of rotationally symmetrical bodies (2, 2, 2?) in such a way that it is faster, reliable and more economical. To this end, the grip (4) comprises grip fingers (26) having rotationally symmetrically holding elements (29, 31) for holding the body (2, 2, 2?), the holding elements (31) being mounted in the grip fingers (26) in such a way that they can be rotated about the rotational axes (29) thereof. In order to grip the body (2, 2, 2?), the grip fingers (26) are displaced on a circular path. A central drive mechanism (22; 35) is respectively provided for the rotational movement of the holding elements (29, 31) of all of the grip fingers and for the rotational movement of all of the grip fingers (26).

Abstract: The invention relates to a method and a device (1) for adjusting the gap dimensions and/or an offset between a movable hood (2) of a motor vehicle and the remaining body (3) of said motor vehicle. The hood (2) is first fitted and retained in a roughly adjusted assembly position so as to be as flush as possible with the body (3), whereupon the hood (2) is finely adjusted such that predefined values are matched as closely as possible for the gap dimensions and/or the offset. In order to be able to adjust the gap dimensions and/or the offset as simply, quickly and flexibly as possible in a contactless manner, actual values (21 ist) for the gap dimensions and/or the offset between the hood (2) and the remaining body (3) are optically detected for the fine adjustment. Triggering signals (24) for at least one actuating member (12) are determined in accordance with the detected actual values (21 ist) and predefined set point values (21-soll) for the gap dimensions and/or the offset.

Abstract: The invention refers to a Method (69) for automatically inserting at least one part (13) into a storage section (15) of a container (11), wherein the storage section (15) comprises a plurality of holder means (17a-d), wherein the part (13) is inserted (103) by means of an insertion tool (49), and wherein the method (69) comprises the step of detecting (93) the position of the holder means (17a-d) by means of at least one optical sensor (51a-d). In order to provide a method for automatically inserting a part into a storage section (15), wherein collisions are avoided it is suggested that the method (69) further comprises the steps of verifying (95) whether the holder means (17a-d) of a certain storage section (15) are available for insertion of the part (13); detecting (99) the orientation of the holder means (17a-d); determining (100) an insertion path (47) along which the part is inserted; and inserting (103) the part (13) into the available storage section (15) along the determined insertion path (47).

Abstract: The invention relates to a method and a device (1) for adjusting the gap dimensions and/or an offset between a movable hood (2) of a motor vehicle and the remaining body (3) of said motor vehicle. The hood (2) is first fitted and retained in a roughly adjusted assembly position so as to be as flush as possible with the body (3), whereupon the hood (2) is finely adjusted such that predefined values are matched as closely as possible for the gap dimensions and/or the offset. In order to be able to adjust the gap dimensions and/or the offset as simply, quickly and flexibly as possible in a contactless manner, actual values (21 ist) for the gap dimensions and/or the offset between the hood (2) and the remaining body (3) are optically detected for the fine adjustment. Triggering signals (24) for at least one actuating member (12) are determined in accordance with the detected actual values (21 ist) and predefined set point values (21-soll) for the gap dimensions and/or the offset.

Abstract: The invention relates to a method and a device (1) for adjusting the gap dimensions and/or an offset between a movable hood (2) of a motor vehicle and the remaining body (3) of said motor vehicle. The hood (2) is first fitted and retained in a roughly adjusted assembly position so as to be as flush as possible with the body (3), whereupon the hood (2) is finely adjusted such that predefined values are matched as closely as possible for the gap dimensions and/or the offset. In order to be able to adjust the gap dimensions and/or the offset as simply, quickly and flexibly as possible in a contactless manner, actual values (21 ist) for the gap dimensions and/or the offset between the hood (2) and the remaining body (3) are optically detected for the fine adjustment. Triggering signals (24) for at least one actuating member (12) are determined in accordance with the detected actual values (21 ist) and predefined set point values (21-soll) for the gap dimensions and/or the offset.

Abstract: The invention concerns a method and a device (10) for closing wedge simulation to set gap dimensions between a movable flap (5; 5a, 5b) of a vehicle and the surrounding body (1) of the vehicle. The flap (5; 5a, 5b) is initially fitted and held in a roughly adjusted installation position in alignment with the body (1). The flap (5; 5a, 5b) is then finely adjusted such that predeterminable gap dimensions can be met with optimum precision. Finally, the flap (5; 5a, 5b) is movably fixed in the finely adjusted installation position on the body (1). To simplify the closing wedge simulation without losing accuracy for fine adjustment of the flap (5; 5a, 5b), the invention proposes to suction the flap (5; 5a, 5b) against a mechanical stop (15) for fine adjustment using a pneumatic suctioning device (16), wherein the mechanical stop (15) is fixed relative to the surrounding body (1) and is freely pivotable about a substantially vertical axis of rotation (13).

Abstract: The invention concerns a portable device (1) for measuring the position, shape and/or size of an object. The device comprises a carrier element (2), at least one transmission unit for generating and transmitting visible radiation towards the object and at least one receiving unit for receiving the radiation imaging the object. The transmission unit and receiving unit are mounted in a defined position relative to each other on the carrier element (2). Modular construction provides high variability of the device (1) so that it can be used flexibly for various applications.

Abstract: The invention concerns a portable device (1) for measuring the position, shape and/or size of an object. The device comprises a carrier element (2), at least one transmission unit for generating and transmitting visible radiation towards the object and at least one receiving unit for receiving the radiation imaging the object. The transmission unit and receiving unit are mounted in a defined position relative to each other on the carrier element (2). Modular construction provides high variability of the device (1) so that it can be used flexibly for various applications.

Abstract: The invention concerns a method and a device (10) for closing wedge simulation to set gap dimensions between a movable flap (5; 5a, 5b) of a vehicle and the surrounding body (1) of the vehicle. The flap (5; 5a, 5b) is initially fitted and held in a roughly adjusted installation position in alignment with the body (1). The flap (5; 5a, 5b) is then finely adjusted such that predeterminable gap dimensions can be met with optimum precision. Finally, the flap (5; 5a, 5b) is movably fixed in the finely adjusted installation position on the body (1). To simplify the closing wedge simulation without losing accuracy for fine adjustment of the flap (5; 5a, 5b), the invention proposes to suction the flap (5; 5a, 5b) against a mechanical stop (15) for fine adjustment using a pneumatic suctioning device (16), wherein the mechanical stop (15) is fixed relative to the surrounding body (1) and is freely pivotable about a substantially vertical axis of rotation (13).

Abstract: The invention relates to a vacuum grip system (10) for gripping at least one object (11a). The vacuum grip system (10) has a base unit (18) and at least two suction units (19, 20) affixed thereto, disposed at right angles to one another, and each having at least one suction gripper (21, 22). At least one of the suction units (19, 20) grasps the object or objects (11a) to be gripped from above, and at least one of the suction units (19,20) grasps the object or objects (11a) from one side. In order to provide The vacuum grip system (10) having maximum flexibility, it is proposed to affix the suction units (19, 20) to the base unit (18) such that, in order to grip the object (11a), the distance between the upper suction unit (19) and the lateral suction unit (20) may be varied. It is further proposed that the vacuum grip system (10) have a mechanical undergripper (25) upon which the gripped object (11a) may be laid.