A wiper system for a vehicle includes a first micromechanical device configured to detect a first ambient condition and a second micromechanical device configured to detect a second ambient condition. The first micromechanical device is configured to communicate with the second micromechanical device, and the first ambient condition is different to the second ambient condition. The first micromechanical device and the second micromechanical device are configured to operate at least one wiper such that the first ambient condition and the second ambient condition are fulfilled. The at least one wiper of the wiper system is configured to remove moisture of a window of the vehicle.

A motor vehicle windshield wiper system includes a windshield wiper and a controller. The controller is configured, in response to a threat of freezing precipitation, to park the windshield wiper in a parked position with a first end of the windshield wiper oriented toward a top edge of the windshield and a second end of the windshield wiper oriented toward a bottom edge of the windshield. A related method of minimizing ice and snow buildup on a windshield wiper is also disclosed.

A method is provided for controlling a wiping-washing process of a rear window cleaning system for a motor vehicle that has at least one windshield cleaning system and a headlight cleaning system for headlights of the motor vehicle. The wiping-washing process of the rear window cleaning system is controlled on the basis of an actuation of the headlight cleaning system and/or the windscreen cleaning system.

A wiper system for vehicles is provided. The system includes a heated wiper blade assembly, a heated cowl assembly and a controller. The controller receives input from one or more sensors or systems and causes a power source to provide, reduce or stop power to heating elements in the blade and/or cowl depending upon sensed conditions. At least some components in the assembly comprise thermally conductive polymers. The system provides surprisingly advantageous results in that it is effective for melting and clearing ice and snow with a lower than expected pull on a power source such as a battery.

A system for automatically deploying a windshield wiper blade to a deployed position includes one or more processors, an actuator coupled to the windshield wiper blade and communicatively coupled to the one or more processors, one or more optical sensors communicatively coupled to the one or more processors that output an optical signal, and one or more memory modules communicatively coupled to the one or more processors. The one or more memory modules store logic that when executed by the one or more processors cause the one or more processors to receive the optical signal output by the one or more optical sensors, detect whether an accumulation of a substance has formed on the vehicle based on the optical signal output by the one or more optical sensors, and deploy, with the actuator, the windshield wiper blade to the deployed position in response to detecting the accumulation of the substance.

A wiper system for vehicles is provided. The system includes a heated wiper blade assembly, a heated cowl assembly and a controller. The controller receives input from one or more sensors or systems and causes a power source to provide, reduce or stop power to heating elements in the blade and/or cowl depending upon sensed conditions. At least some components in the assembly comprise thermally conductive polymers. The system provides surprisingly advantageous results in that it is effective for melting and clearing ice and snow with a lower than expected pull on a power source such as a battery.

A wiper system for vehicles is provided. The system includes a heated wiper blade assembly, a heated cowl assembly and a controller. The controller receives input from one or more sensors or systems and causes a power source to provide, reduce or stop power to heating elements in the blade and/or cowl depending upon sensed conditions. At least some components in the assembly comprise thermally conductive polymers. The system provides surprisingly advantageous results in that it is effective for melting and clearing ice and snow with a lower than expected pull on a power source such as a battery.

A wiper system for vehicles is provided. The system includes a heated wiper blade assembly, a heated cowl assembly and a controller. The controller receives input from one or more sensors or systems and causes a power source to provide, reduce or stop power to heating elements in the blade and/or cowl depending upon sensed conditions. At least some components in the assembly comprise thermally conductive polymers. The system provides surprisingly advantageous results in that it is effective for melting and clearing ice and snow with a lower than expected pull on a power source such as a battery.

A temperature sensor system for a vehicle includes a temperature sensor assembly having a thermally insulating body, a temperature sensing element thermally insulated within the body, and a thermally conductive contacting element exposed externally of the body and in thermal communication with the temperature sensing element. The thermally conductive contacting element is urged into contact with an interior cabin side of a windshield of the vehicle for sensing the temperature of the vehicle windshield. A controller, responsive to the temperature sensing element and another temperature sensing element and a humidity sensing element of the vehicle, is operable to calculate an ambient dew point and to control a cabin climate control system of the vehicle responsive to the calculated ambient dew point. The other temperature sensing element is mounted in the vehicle away from the vehicle windshield.

A method of preventing a windshield wiper from freezing to a windshield of a vehicle is provided. The method broadly includes the steps of: (a) receiving information relating to an ambient condition of the vehicle; (b) switching power to a motor for driving the windshield wiper in a first direction if the received information indicates an adverse ambient condition of the vehicle; (c) sensing current drawn by the motor; (d) comparing an initial sensed current drawn by the motor when power is initially switched to the motor to a subsequent sensed current drawn by the motor a period after power is initially switched to the motor; and (e) periodically reversing the motor for driving the windshield wiper in a second direction or the first direction until the subsequent sensed current is less than the initial sensed current.