Abstract: A method, a control arrangement and a sensor target for enabling calibration of vehicle sensors. The sensor target comprises a plurality of recognition zones, each comprising a recognition pattern dedicated to a distinct sensor modality, for enabling calibration of vehicle sensors of the respective sensor modality; and localization dependent information associated with at least one recognition zone, provided to the vehicle via a vehicle sensor reading.

Abstract: The invention relates to a method of controlling a working machine. The method includes monitoring a detection region behind the working machine by means of a rear detection device; and determining whether the working machine is traveling forward or in reverse. The method further includes disregarding an object in the detection region detected by the rear detection device when the working machine is traveling forward. The invention also relates to a control system for controlling a working machine having a rear detection device arranged to monitor a detection region behind the working machine. The invention also relates to a working machine.

Abstract: Method and control unit in a vehicle comprising a digital rear view mirror, for detecting an object situated outside a default view of a display of the digital rear view mirror and visualizing the detected object for a driver of the vehicle. The method comprises detecting the object, situated outside the default view of the display, by a sensor; and adjusting the field of view of a subset of the display by widening the viewing angle so that the object becomes visible for the driver in the subset of the display, while the main portion of the display outputs the default view at a default viewing angle.

Abstract: A method, computer program, apparatus, and system for authentication of devices in a network of devices, and more specifically to a challenge-response authentication in which one trusted device presents a question (“challenge”) and another party must provide a valid answer (“response”) to be authenticated. The challenge includes processing data by an application specific integrated circuit (ASIC).

Abstract: A gyratory crusher includes an inner and an outer crushing shell. The outer crushing shell has three regions along its axial length including: an inlet region that tapers radially inward from an uppermost first end; a crushing region that extends radially inward from a second lowermost end; and a radially innermost shoulder region that is positioned axially between the inlet and crushing regions. An angle of inclination of a radially inward facing surface at the inlet and shoulder regions and the axial length of the crushing surface are designed to optimize crushing capacity in addition maximizing reduction.

Abstract: Method and control unit in a vehicle comprising a digital rear view mirror, for detecting an object situated outside a default view of a display of the digital rear view mirror and visualizing the detected object for a driver of the vehicle. The method comprises detecting the object, situated outside the default view of the display, by a sensor; and adjusting the field of view of a subset of the display by widening the viewing angle so that the object becomes visible for the driver in the subset of the display, while the main portion of the display outputs the default view at a default viewing angle.

Abstract: A method (400) and a 3D camera (110) for a vehicle for detecting an object (130) in an area (140) for collecting (401) measurement data related to the area (140) by a sensor (310) in the 3D camera (110) using a first sensor setting, in addition, reception (402) of measurement data related to the area (140) from a radar (120), and detection (405) of the object (130) based on interpretation of collected (401) measurement data by the camera together with measurement data received (402) from the radar (120).

Abstract: A gyratory crusher includes an inner and an outer crushing shell. The outer crushing shell has three regions along its axial length including: an inlet region that tapers radially inward from an uppermost first end; a crushing region that extends radially inward from a second lowermost end; and a radially innermost shoulder region that is positioned axially between the inlet and crushing regions. An angle of inclination of a radially inward facing surface at the inlet and shoulder regions and the axial length of the crushing surface are designed to optimise crushing capacity in addition maximising reduction.

Abstract: A method, computer program, apparatus, and system for authentication of devices in a network of devices, and more specifically to a challenge-response authentication in which one trusted device presents a question (“challenge”) and another party must provide a valid answer (“response”) to be authenticated. The challenge includes processing data by an application specific integrated circuit (ASIC).

Abstract: A gyratory crusher outer crushing shell and a crushing shell assembly. The crushing shell includes a radially inward facing crushing surface and a radially outward facing mount surface provided with radially outward projecting contact regions to contact the topshell or an intermediate spacer ring. A ledge or groove providing an abutment face is positioned at or axially above the upper contact region to positionally support a sealing ring for positioning between the crushing shell and the topshell or intermediate spacer ring.

Abstract: A method (400) and a 3D camera (110) for a vehicle for detecting an object (130) in an area (140) for collecting (401) measurement data related to the area (140) by a sensor (310) in the 3D camera (110) using a first sensor setting, in addition, reception (402) of measurement data related to the area (140) from a radar (120), and detection (405) of the object (130) based on interpretation of collected (401) measurement data by the camera together with measurement data received (402) from the radar (120).

Abstract: A gyratory crusher outer crushing shell and a crushing shell assembly. The crushing shell includes a radially inward facing crushing surface and a radially outward facing mount surface provided with radially outward projecting contact regions to contact the topshell or an intermediate spacer ring. A ledge or groove providing an abutment face is positioned at or axially above the upper contact region to positionally support a sealing ring for positioning between the crushing shell and the topshell or intermediate spacer ring.

Abstract: A gyratory crusher outer crushing shell. The outer crushing shell comprises an upper contact surface region that is divided into a plurality of elongate circumferentially extending shoulders. The shoulders are separated by recessed gap regions adapted to accommodate a suitable backing material to structurally reinforce the shell. A channel extends circumferentially around the shell in the outward facing surface to axially separate the upper contact surface region from a lower contact surface region. The channel is also adapted to accommodate the backing material.

Abstract: A gyratory crusher outer crushing shell. The outer crushing shell comprises an upper contact surface region that is divided into a plurality of elongate circumferentially extending shoulders. The shoulders are separated by recessed gap regions adapted to accommodate a suitable backing material to structurally reinforce the shell. A channel extends circumferentially around the shell in the outward facing surface to axially separate the upper contact surface region from a lower contact surface region. The channel is also adapted to accommodate the backing material.

Abstract: A gyratory crusher outer crushing shell has three regions along its axial length including: an inlet region that tapers radially inward from an uppermost first end; a crushing region that extends radially inward from a second lowermost end; and a radially innermost shoulder region that is positioned axially between the inlet and crushing regions. An angle of inclination of a radially inward facing surface at the inlet and shoulder regions and the axial length of the crushing surface are designed to optimise crushing capacity in addition maximising reduction.

Abstract: The present invention concerns an arrangement for in situ mounting of rotor blades to a rotor hub of a wind power plant comprising rotor blades, a rotor hub (40), a disc (1), a means for rotation (30) of the disc (1) around its axis. The disc (1) is in connection with the rotor hub (40) in such a way that when the disc (1) rotates a certain degree of angle around its axis (3) it will cause the rotor hub (40) to rotate the same degree of angle around the axis of the rotor hub. When the means for rotation (30) comes into a desired position, the disc (1) is secured by a securing means (20; 36, 37).

Abstract: According to the present disclosure, a pressurization system for use in a wind turbine, the wind turbine including at least one rotor blade to capture wind energy and a shaft for transferring the wind energy to a generator is provided. The pressurization system includes at least one pressurizer that is adapted to be powered by the kinetic energy of the shaft and to provide a pressurized fluid to at least one hydrostatic bearing.

Abstract: A braking system for a wind turbine is provided. The system includes one or more motors for driving a part of the wind turbine, a first group of brakes for braking the part of the wind turbine, and a second group of brakes for braking the part of the wind turbine. The first group of brakes is in a normally closed condition and the second group of brakes is in a normally open condition, so that a default brake torque can be selectively chosen that is less than a maximum brake torque.

Abstract: A braking system for a wind turbine is provided. The system includes one or more motors for driving a part of the wind turbine, a first group of brakes for braking the part of the wind turbine, and a second group of brakes for braking the part of the wind turbine. The first group of brakes is in a normally closed condition and the second group of brakes is in a normally open condition, so that a default brake torque can be selectively chosen that is less than a maximum brake torque.

Abstract: A locking device for locking a turbine blade of a wind power plant at a predetermined pitch angle, which wind power plant includes a rotor hub and at least one turbine blade where the blade root of the at least one turbine blade is connected to the rotor hub through a pitch bearing so that the pitch angle of the at least one turbine blade is adjustable by turning of the at least one turbine blade about its longitudinal axis relative to the rotor hub and wherein the device for locking the turbine blade includes a mechanical snap-in mechanism which in a locked position prevents the at least one turbine blade from turning about its longitudinal axis thus fixating the at least one turbine blade in the predetermined pitch angle.