The invention relates to a wiper motor (10), with a shaft (28) for driving a wiper arm (1), wherein the shaft (28) projects through an opening (29) of a housing (15) and wherein in the region of the opening (29) the shaft (28) is mounted radially in a bore in an at least substantially sleeve-shaped element (30; 30a), wherein the sleeve-shaped element (30; 30a) is fixed at least axially in the region of the housing (15), and wherein the sleeve-shaped element (30; 30a) has at least two different cross-sections (33; 33a, 34), a first cross-section (33; 33a) which is designed to protrude axially at least through the opening (29) and a second cross-section (34) which is designed to be axially fixed within said opening (29) or within a receiving space (25) of said housing (15).

A task management device includes a control unit that detects a deterioration of an internal environment of a vehicle as an environmental deterioration during a period in which the vehicle to be operated in a mode in accordance with an application is operated in a first mode, calculates a time required for maintenance of the internal environment of the vehicle in accordance with the detected environmental deterioration and determines whether the maintenance is completed by a mode switching time limit for switching the mode of the vehicle to a second mode that is different from the first mode, and executes operational control in accordance with a determination result obtained.

A task management device includes a control unit that detects a deterioration of an internal environment of a vehicle as an environmental deterioration during a period in which the vehicle to be operated in a mode in accordance with an application is operated in a first mode, calculates a time required for maintenance of the internal environment of the vehicle in accordance with the detected environmental deterioration and determines whether the maintenance is completed by a mode switching time limit for switching the mode of the vehicle to a second mode that is different from the first mode, and executes operational control in accordance with a determination result obtained.

A system and method for robust automatic control of an air-conditioning system in a vehicle includes at least one sensor configured to continuously capture technical driving parameters of the vehicle. The system has a computing unit configured to determine a current air quality from the captured technical driving parameters by way of a suitable algorithm. The system has a control unit configured to control the air-conditioning system in the vehicle, wherein the control of the air-conditioning system includes activating the recirculation circuit of the air-conditioning system and/or activating the fresh-air circuit of the air-conditioning system with reference to the determined air quality.

A vehicle washing system includes a frame disposed above a vehicle treatment area, and an extendable and retractable scissor mechanism coupled to the frame. A rotatable top brush is coupled to a bottom end of the scissor mechanism, and the scissor mechanism is extendable downward to lower the top brush into engagement with a vehicle body and retractable upward to remove the brush from engagement with the vehicle body. The scissor mechanism may include a brush support flange coupled to a bottom end of the scissor mechanism. An anti-spin member may extend from the support member to the scissor mechanism to prevent bending of the scissor mechanism in response to rotating to the top brush. The anti-spin member may be in the form of a fork that slidably engages a protrusion of the scissor mechanism.

Vehicles and methods are disclosed. A vehicle includes one or more imaging sensors, one or more processors, and one or more non-transitory memory modules storing machine-readable instructions. Executing the machine-readable instructions causes the one or more processors to receive identification information from a service device. Executing the machine-readable instructions causes the one or more processors to obtain, using the one or more imaging sensors, image data corresponding to identifying indicia of the service device. Executing the machine-readable instructions causes the one or more processors to authenticate the service device based on the identification information and the identifying indicia. Executing the machine-readable instructions causes the one or more processors to initiate a service in response to authentication of the service device.

Vehicles and methods are disclosed. A vehicle includes one or more imaging sensors, one or more processors, and one or more non-transitory memory modules storing machine-readable instructions. Executing the machine-readable instructions causes the one or more processors to receive identification information from a service device. Executing the machine-readable instructions causes the one or more processors to obtain, using the one or more imaging sensors, image data corresponding to identifying indicia of the service device. Executing the machine-readable instructions causes the one or more processors to authenticate the service device based on the identification information and the identifying indicia. Executing the machine-readable instructions causes the one or more processors to initiate a service in response to authentication of the service device.

A vehicle wash system includes a vehicle treatment area and an overhead frame portion supporting a rotational brush that is translatable relative to a vehicle disposed within the vehicle treatment area. The brush may rotate in the same rotational direction during a first translation direction and a second translation direction of the brush along the vehicle. During one direction of translation, the brush rotates at a first rotational speed, and in the opposite direction of translation, the brush rotates at increased rotational speed. The system may include a pair of side brushes, with the brushes rotating in opposite rotational directions, but maintaining their rotational directions during both directions of translation.

A vehicle wash system includes a vehicle treatment area and an overhead frame portion supporting a pair of side brushes. The side brushes are configured to treat the lateral sides of the vehicle and may also treat the front and back of the vehicle. The side brushes are configured to pivot between a vertical position and an outwardly angled position, in which the side brushes are generally aligned with the side glass of the vehicle windows. The side brushes may travel along the side of the vehicle in both the vertical and pivoted orientations. The side brushes may make multiple passes along the side of the vehicle, and the side brushes may change orientation during or between passes to treat different segments of the vehicle. The side brushes may be oriented vertically at a location of a vehicle antenna to avoid the antenna.

A vehicle wash system includes a vehicle treatment area and an overhead frame portion supporting a pair of side brushes. The side brushes are configured to treat the lateral sides of the vehicle and may also treat the front and back of the vehicle. The side brushes are configured to pivot between a vertical position and an outwardly angled position, in which the side brushes are generally aligned with the side glass of the vehicle windows. The side brushes may travel along the side of the vehicle in both the vertical and pivoted orientations. The side brushes may make multiple passes along the side of the vehicle, and the side brushes may change orientation during or between passes to treat different segments of the vehicle. The side brushes may be pivoted at a side mirror location of the vehicle.