Method for controlling a system for wiping and washing a window (2) of a vehicle, comprising at least two wiping cycles comprising: a first step in which the wiper blade member (1) is actuated in order to move over the window (2) between a first starting position (P0) and an end position (P2), and a second step in which the wiper blade member (1) is actuated in order to move over the window (2) in the opposite direction from the end position (P2) as far as a second starting position (P1),
characterised in that the first cycle which is carried out wipes all the wiping zone with means (10, 13, 14) for projecting a washing liquid which are actuated at least during the first step, and in that a second wiping cycle has the same first starting position (P0) and a second starting position (P1) which is offset towards the end position (P2) relative to the first starting position (P0).

An accessory system for a vehicle includes an attachment element bonded to an in-cabin windshield surface at a first windshield location and an attachment member attached at the in-cabin windshield surface at a second windshield location. An interior rearview mirror assembly has a mirror support that has a mirror mount configured to mount the mirror assembly to the attachment element. A module is configured to be received by and be supported by the attachment member attached at the windshield. With the module received by and supported by the attachment member at the windshield, a camera of the module views through the windshield and is part of a driver assistance system of the vehicle. With the module received by and supported by the attachment member at the windshield, the mirror mount can be mounted to and demounted from the attachment element without demounting the module from the attachment member.

A wiper system according to the present invention includes wiper blades (2a, 2b) that perform a reciprocating wiping operation on a windshield (3), and a raindrop sensor (9) that detects the current amount of rainfall based on water droplets adhering to the windshield (3). If rainfall more than or equal to a predetermined amount is detected by the raindrop sensor (9), a heavy rain mode in which a wiping range of the wiper blades (2a, 2b) is made narrower than in a normal wiping operation is carried out. In the heavy rain mode, the wiper blade (2a) arranged on the driver's side is activated at high speed (Hi) within a heavy rain time wiping area X set near the forward field of view of the driver to ensure the field of view of the driver.

A method of minimizing ice buildup on a windshield of a vehicle is provided. The method includes the steps of: (a) monitoring a state of the vehicle; (b) determining a state of the windshield wiper; (c) determining an ambient temperature of the vehicle; and (d) initiating a timer when the state of the vehicle changes from an on state if the ambient temperature is below a threshold temperature and the state of the windshield wiper prior to the vehicle changing to the off state is an on state, and turning the windshield wiper to the on state after a period of time. The windshield wiper may remain on at least through a full cycle from a park zone, to a fully extended position, and back to the park zone. The wiper may remain on for a predetermined period of time determined based upon the ambient temperature or other condition.

A wiper system 1 has a wiper blade 5 for performing a reciprocating wiping operation on a windshield glass 6 and a brushless motor 2 for causing the wiper blade 5 to perform the reciprocating wiping operation. The motor used as the brushless motor 2 is provided with a rotary shaft for reciprocating the wiper blade 5, has a degree of operation freedom in three axial directions, and is rotatable about axes of two directions orthogonal to the rotary shaft. The wiper blade 5 operates at error angles different in direction between during a forward-path wiping operation and during a return-path wiping operation. When the wiper blade 5 reaches a reversing position, the brushless motor 2 is made to rotate about an axis extending in a extending direction of the wiper blade 5 to change the error angle .

A wiper system 1 has a wiper blade 5 for performing a reciprocating wiping operation on a windshield glass 6 and a brushless motor 2 for causing the wiper blade 5 to perform the reciprocating wiping operation. The motor used as the brushless motor 2 is provided with a rotary shaft for reciprocating the wiper blade 5, has a degree of operation freedom in three axial directions, and is rotatable about axes of two directions orthogonal to the rotary shaft. The wiper blade 5 operates at error angles different in direction between during a forward-path wiping operation and during a return-path wiping operation. When the wiper blade 5 reaches a reversing position, the brushless motor 2 is made to rotate about an axis extending in a extending direction of the wiper blade 5 to change the error angle .

Disclosed is an apparatus for controlling a wiper motor for a wiper system. The wiper motor includes a double cam plate rotated by rotational force of a motor, and internal contact points formed by a P-terminal and an E-terminal disconnected/connected by the double cam plate. The double cam plate includes a first cam plate and a second cam plate for connecting the P-terminal and the E-terminal, and a center plate between the first and second cam plates. The apparatus includes a circuit line connecting the P-terminal with an off terminal of a low relay, and a control unit turning off the low relay simultaneously when the P-terminal and the E-terminal connected by the first cam plate are disconnected when a multifunctional switch is turned off. The apparatus decreases electromotive force applied to the wiper motor while the center plate is in contact with the P-terminal.

Disclosed is an apparatus for controlling a wiper motor for a wiper system. The wiper motor includes a double cam plate rotated by rotational force of a motor, and internal contact points formed by a P-terminal and an E-terminal disconnected/connected by the double cam plate. The double cam plate includes a first cam plate and a second cam plate for connecting the P-terminal and the E-terminal, and a center plate between the first and second cam plates. The apparatus includes a circuit line connecting the P-terminal with an off terminal of a low relay, and a control unit turning off the low relay simultaneously when the P-terminal and the E-terminal connected by the first cam plate are disconnected when a multifunctional switch is turned off. The apparatus decreases electromotive force applied to the wiper motor while the center plate is in contact with the P-terminal.

A motor apparatus provided with a connector unit (40) to which an external connector is connected, wherein the connector unit (40) has a plurality of conductive members (64, 65, 66) arranged over a base portion (50) and a connector connecting portion (70) provided with a plug-in hole in which the external connector is plugged, wherein the conductive members (64, 65, 66) respectively include connector-side connecting portions (64a, 65a, 66a) connected to the external connector so as to face the connector connecting portion (70) from a first direction reversed to a plug-in direction of the external connector to the plug-in hole and base-side connecting portions (64b, 65b, 66b) connected to terminals or wirings provided in the base portion (50), wherein the connector-side connecting portions (64a, 65a, 66a) are respectively inserted into a plurality of insertion holes (74, 75, 76) provided at positions different from each other in a second direction intersecting the first direction, and wherein the base-side connecting portions (64b, 65b, 66b) are respectively arranged at the same position in the second direction.

A motor apparatus provided with a connector unit (40) to which an external connector is connected, wherein the connector unit (40) has a plurality of conductive members (64, 65, 66) arranged over a base portion (50) and a connector connecting portion (70) provided with a plug-in hole in which the external connector is plugged, wherein the conductive members (64, 65, 66) respectively include connector-side connecting portions (64a, 65a, 66a) connected to the external connector so as to face the connector connecting portion (70) from a first direction reversed to a plug-in direction of the external connector to the plug-in hole and base-side connecting portions (64b, 65b, 66b) connected to terminals or wirings provided in the base portion (50), wherein the connector-side connecting portions (64a, 65a, 66a) are respectively inserted into a plurality of insertion holes (74, 75, 76) provided at positions different from each other in a second direction intersecting the first direction, and wherein the base-side connecting portions (64b, 65b, 66b) are respectively arranged at the same position in the second direction.