Aspects of the present disclosure are directed to methods for mounting a segmented generator of a wind turbine, wherein the segmented generator for the operation of the wind turbine is formed from two or more generator segments, wherein the generator segments each have a stator segment and a rotor segment, wherein the stator segment for fastening the stator segment to a machine carrier flange of a machine carrier has a stator flange and the rotor segment for fastening to a rotor carrier of a main bearing has a rotor flange, wherein the two or more generator segments in the circumferential direction (U) each extend between two connection interfaces (V1, V2) which are formed for connection with connection interfaces (V1, V2) of generator segments arranged adjacent in the circumferential direction (U).

Aspects of the present disclosure are directed to methods for mounting a segmented generator of a wind turbine, wherein the segmented generator for the operation of the wind turbine is formed from two or more generator segments, wherein the generator segments each have a stator segment and a rotor segment, wherein the stator segment for fastening the stator segment to a machine carrier flange of a machine carrier has a stator flange and the rotor segment for fastening to a rotor carrier of a main bearing has a rotor flange, wherein the two or more generator segments in the circumferential direction (U) each extend between two connection interfaces (V1, V2) which are formed for connection with connection interfaces (V1, V2) of generator segments arranged adjacent in the circumferential direction (U).

An imaging system for capturing spatial-omic images of biological tissue samples may include an imaging chamber configured to secure a biological tissue sample placed in the imaging system; a Time Delay and Integration (TDI) imager comprising at least one scan line; a light source configured to illuminate an area on the biological tissue sample that is being captured by the TDI imager; and a controller configured to cause the TDI imager to scan the biological tissue sample using one or more TDI scans of the biological tissue sample.

An imaging system for capturing spatial-omic images of biological tissue samples may include an imaging chamber configured to secure a biological tissue sample placed in the imaging system; a Time Delay and Integration (TDI) imager comprising at least one scan line; a light source configured to illuminate an area on the biological tissue sample that is being captured by the TDI imager; and a controller configured to cause the TDI imager to scan the biological tissue sample using one or more TDI scans of the biological tissue sample.

Impregnation plant for axial symmetrical components of electric motors, including: a support frame, one or more component heating stations, one or more motor-driven equipment for supporting and handling the components, one or more component impregnation equipment and one or more component transport and loading/unloading equipment. Each supporting and handling motor-driven equipment includes at least one gripper for a respective component, motor-driven devices for rotating the grippers and motor-driven apparatus for translatorily moving the individual motor-driven support and handling equipment. Each gripper includes an annular body having an axial symmetrical internal cavity that has a maximum dimension greater than the maximum dimension of each component, so the internal cavity can house the component internally thereto. Each annular body includes at least one gripper facing the internal cavity to grip the outer side surface of each component and hold it in the internal cavity.

Impregnation plant for axial symmetrical components of electric motors, including: a support frame, one or more component heating stations, one or more motor-driven equipment for supporting and handling the components, one or more component impregnation equipment and one or more component transport and loading/unloading equipment. Each supporting and handling motor-driven equipment includes at least one gripper for a respective component, motor-driven devices for rotating the grippers and motor-driven apparatus for translatorily moving the individual motor-driven support and handling equipment. Each gripper includes an annular body having an axial symmetrical internal cavity that has a maximum dimension greater than the maximum dimension of each component, so the internal cavity can house the component internally thereto. Each annular body includes at least one gripper facing the internal cavity to grip the outer side surface of each component and hold it in the internal cavity.