A system and method for finding dents on an automobile is described herein. The system, in one embodiment, can be a booth that has a support structure, a plurality of wall sections, a roof, and interior surface defined at least in part by the wall sections and the roof, and a first geometric repeating pattern on a first region of the interior space. The method in one embodiment, can be receiving an automobile within the booth described above, illuminating the booth to cause the first geometric repeating pattern of the booth to reflect off a surface of said automobile; and identifying presence of defects using a reflected pattern, the reflected pattern a reflected image of the first geometric repeating pattern on the automobile.

A system and method for finding dents on an automobile is described herein. The system, in one embodiment, can be a booth that has a support structure, a plurality of wall sections, a roof, and interior surface defined at least in part by the wall sections and the roof, and a first geometric repeating pattern on a first region of the interior space. The method in one embodiment, can be receiving an automobile within the booth described above, illuminating the booth to cause the first geometric repeating pattern of the booth to reflect off a surface of said automobile; and identifying presence of defects using a reflected pattern, the reflected pattern a reflected image of the first geometric repeating pattern on the automobile.

A method of determining a vehicle health score for a vehicle includes receiving location information associated with a location of the vehicle and identifying at least one location-specific health factor based on the received location information. The method further includes receiving diagnostic data from the vehicle, with the diagnostic data including data points associated with several different heath factors including the at least one location-specific health factor, each health factor being associated with an acceptable condition. The received diagnostic data is compared with the acceptable conditions for each health factor and a preliminary score for each health factor is assigned based on the comparison. A weight is assigned to each of the preliminary scores and a comprehensive vehicle health score is calculated based on each of the weighted preliminary scores. The comprehensive vehicle health score is then displayed on a display.

A power tool includes a wrench head having a rotary socket, and a spanner tool mounted in the rotary socket, wherein the rotary socket grips a first component and the spanner tool grips a second components, the first and second component being adjacent.

A power tool includes a wrench head having a rotary socket, and a spanner tool mounted in the rotary socket, wherein the rotary socket grips a first component and the spanner tool grips a second components, the first and second component being adjacent.

A method for indirectly deriving a systematic dependence for a system behavior of a system component of a cleaning system of a motor vehicle. The cleaning system is adapted for cleaning at least one surface of the motor vehicle by means of a cleaning process adapted for a resource efficient cleaning. Additionally, a diagnosing method, a method for selecting a resolution strategy, a use of a resolution strategy, a cleaning method, a cleaning system, and a motor vehicle are disclosed.

A service vehicle provides a platform for servicing a container handling vehicle while on a grid-based rail system of a three-dimensional storage grid of an automated storage system for storing storage containers. The service vehicle includes two or more wheel modules. Each module having a first set of wheels configured to move the vehicle along a first lateral direction of the grid-based rail system and a second set of wheels configured to move the vehicle along a second lateral direction of the grid-based rail system. The second direction is perpendicular to the first direction. A platform is mounted on the two or more wheel modules. The platform includes an enclosure that has at least one opening that can be closed by a barrier. The platform has a set of tracks matching the width of the tracks on the grid.

A service vehicle provides a platform for servicing a container handling vehicle while on a grid-based rail system of a three-dimensional storage grid of an automated storage system for storing storage containers. The service vehicle includes two or more wheel modules. Each module having a first set of wheels configured to move the vehicle along a first lateral direction of the grid-based rail system and a second set of wheels configured to move the vehicle along a second lateral direction of the grid-based rail system. The second direction is perpendicular to the first direction. A platform is mounted on the two or more wheel modules. The platform includes an enclosure that has at least one opening that can be closed by a barrier. The platform has a set of tracks matching the width of the tracks on the grid.

A target alignment system for calibrating a safety sensor mounted on a vehicle with front and rear wheels by locating an optimum target position upon a horizontal surface for accurate calibration of the sensor. The target alignment system comprises a plurality of visual guide projectors and a pair of target assemblies which project a visible guide line perimeter around the vehicle, the perimeter including parallel longitudinal lines on either side of the vehicle, a lateral alignment guide line crossing the longitudinal lines in front of the vehicle, and a center guide line colinear with the vehicle center line. The front and rear wheels of the vehicle are longitudinally aligned causing the vehicle thrust line to match the vehicle center line. One of the visual guide projectors projects a transverse line across the center guide line, creating an intersection point which marks the optimum target position.

A target alignment system for calibrating a safety sensor mounted on a vehicle with front and rear wheels by locating an optimum target position upon a horizontal surface for accurate calibration of the sensor. The target alignment system comprises a plurality of visual guide projectors and a pair of target assemblies which project a visible guide line perimeter around the vehicle, the perimeter including parallel longitudinal lines on either side of the vehicle, a lateral alignment guide line crossing the longitudinal lines in front of the vehicle, and a center guide line colinear with the vehicle center line. The front and rear wheels of the vehicle are longitudinally aligned causing the vehicle thrust line to match the vehicle center line. One of the visual guide projectors projects a transverse line across the center guide line, creating an intersection point which marks the optimum target position.