A first driven lever of a vehicle wiper device has a proximal end pivotally connected to a distal end of a first driving lever. A second driven lever has a proximal end pivotally connected to a distal end of the first driven lever and a distal end pivotally connected to a distal end of a second driving lever. A first wiper arm operates integrally with the second driven lever and has a distal end to which a first wiper blade is connected. A swing transmission mechanism transmits a driving force to the first driving lever. The swing transmission mechanism includes a swing crank arm integrally rotatable with a rotation shaft of a single drive source. An extension-contraction transmission mechanism transmits a driving force to the second driving lever. The extension-contraction transmission mechanism includes an extension-contraction crank arm integrally rotatable with the rotation shaft of the drive source.

A wiper linkage system directly transmits rotating force of a motor to one wiper arm. The wiper linkage system includes: a gear housing installed on a wiper motor, a pipe rod installed on the gear housing, a crank arm installed on an output shaft of the wiper motor, a first wiper arm installed on a first end of the crank arm by a rotating shaft, a pivot housing assembled with the pipe rod, and a second wiper arm operated by a link structure including a link unit coupled to a second end of the crank arm and the pivot housing. In particular, a first end of the pipe rod is fixed to a vehicle body by a pipe mounting.

The present invention concerns a key (1) for locking a link including a U-section and a crank of a linkage of a wiper mechanism in a transport position, characterized in that it comprises: a shaft (11) having at one end a radial holding excrescence (13) and at the other end an enlarged head (15) intended to cooperate with a hollow part of the U-section forming the link, and a first radial finger (17) configured to be housed in a slot for locking the link in the transport position.

A wiper device including: a power supplying circuit including plural switching elements, the power supplying circuit supplying, to a wiper motor, voltage that has been converted in accordance with switching control of the plural switching elements; a temperature detecting section detecting a temperature relating to a temperature of at least one of the switching elements among the plural switching elements; a current detecting section detecting current flowing to any of the switching elements among the plural switching elements; and a control section that, in a case in which the current detected by the current detecting section exceeds a limit current at the temperature detected by the temperature detecting section, carries out switching control of the switching elements such that the voltage supplied to the wiper motor decreases.

A control section is configured to perform rotation control of a wiper motor that causes a wiper blade to perform a wiping operation over a windshield, and a test unit is capable of communicating with the control section at a characteristic communication speed of the control section, and employs a specific communication with the control section at the characteristic communication speed to enable testing of the control section and the wiper motor by communication at a test communication speed of not less than the characteristic communication speed.

A voltage divider circuit is configured by a resistor having one end connected to a positive electrode of a battery configuring a power source and another end connected to a first terminal that is a motor terminal on one side of a wiper motor, and a FET having one end connected to the first terminal and another end grounded. The voltage divider circuit lowers a voltage of the battery to a test voltage that does not cause the wiper motor to rotate. A microcomputer detects a detected voltage that is a voltage output from the voltage divider circuit to a second terminal that is a motor terminal on the other side of the wiper motor via the first terminal of the wiper motor and the wiper motor, and computes a motor terminal voltage, this being a potential difference between the first terminal and the second terminal, from the detected voltage.

A vehicle wiper device is provided including a first motor that swings a wiper arm such that a wiper blade coupled to a leading end portion of the wiper arm wipes a windshield, a second motor that extends or retracts an extension and retraction mechanism provided to the wiper arm in order to change a wiping range of the wiper blade, and a controller that controls rotation of the first motor such that the first motor rotates at a rotation speed corresponding to a wiping speed, and that controls rotation of the second motor so as to extend or retract the extension and retraction mechanism by an extension or retraction amount corresponding to the wiping speed during a wiping operation.

A wiper control device that properly detects restriction of a wiper blade according to a travel distance of the wiper blade. When a state in which a rotation speed of an output shaft calculated from a rotation angle of the output shaft detected by a rotation angle sensor is equal to or slower than a speed threshold defined according to a travel distance of the wiper blade and in which a current detected by a current detector is equal to or larger than a current threshold continues for a predetermined determination period, a microcomputer stops a wiper motor or reverses a direction of a wiping action of the wiper blade.

The versatility of a water collecting member is raised while improving the ease of assembly of the water collecting member. A water collecting member 80 is formed with plural first marks 90 serving as markers for assembly of the water collecting member 80 to a first pivot holder 20. The first pivot holder 20 is formed with a second mark 92 serving as a guide for the correct assembly orientation of the water collecting member 80 to the first pivot holder 20. The second mark 92 is formed corresponding to one out of the plural first marks 90, and is configured so as to form a pair with that first mark 90. The water collecting member 80 can be assembled in the correct position by aligning the second mark 92 and the first mark 90 that form a pair when assembling the water collecting member 80 to the first pivot holder 20. This thereby enables incorrect assembly of the water collecting member 80 to be prevented when assembling the water collecting member 80 to the first pivot holder 20 in cases in which a universal water collecting member 80 is employed in various vehicle models.

A windshield wiper system for an aircraft is provided and includes a motor, an output shaft, a wrap spring and crank rocker mechanism (WSCRM) to which the motor and the output shaft are coupled and a controller. By way of the WSCRM, first directional rotation input to the WSCRM from the motor via a two-stage gear reduction is converted such that the output shaft drives wiper blade oscillation through a first sweep angle and second directional rotation input to the WSCRM from the motor is converted such that the output shaft drives wiper blade oscillation through a second sweep angle. The controller is configured to control the motor such that the first directional rotation is continuously or non-continuously input during first or second flight conditions, respectively, and the second directional rotation is continuously input during third flight conditions.