Abstract: A power transmission device include: a differential having three rotational elements; and a connection switching device that selectively switches a connection relationship among an input shaft, a first output shaft, a second output shaft, and the three rotational elements. Further, the connection switching device selectively fixes any one rotational element to a fixing member, the second power source is coupled to rotational elements other than the rotational element fixed to the fixing member, the differential can be switched between modes including a first mode where any one rotational element among the three rotational elements is coupled to the input shaft, one of the remaining rotational elements is fixed to the fixing member, and the other is coupled to the first output shaft, and a second mode where the three rotational elements are respectively coupled to the second power source, the first output shaft, and the second output shaft.

Abstract: A continuously variable transmission includes: a primary pulley; a secondary pulley; a power transmission member; a case; and a shield member. The shield member is disposed between an inner surface of the case and a first pulley that is one of the primary pulley and the secondary pulley, at a position on an opposite side of the first pulley from a second pulley that is another one of the primary pulley and the secondary pulley. The shield member includes a plate part that is configured to cover a part of an outer circumference of the first pulley, where the power transmission member is wound, such that the plate part intersects with a minimum width extension line and a maximum width extension line.

Abstract: A variable transmission system for a vehicle is configured such that, when a magnitude of a hydraulic pressure detected by an hydraulic pressure sensor is a first predetermined value or more, a chord portion of a chain belt is pressed such that a raceway length of the chain belt is extended by at least a circumferential extension amount of the chain belt at the time when the magnitude of the hydraulic pressure is the first predetermined value. Hereby, it is possible to restrain the chain belt from coming off from a sheave even in a low vehicle speed range, at a low cost, without causing a fuel efficiency decrease and a driving torque decrease of the vehicle.

Abstract: Provided is a hybrid vehicle including: an engine longitudinally positioned on a front side of a vehicle body; a first motor; a rear wheel to which output torque of the engine and the first motor is transmitted to generate driving power; a second motor; and a front wheel to which output torque of the second motor is transmitted to generate driving power. Both the first motor and the second motor are disposed between the engine and an automatic transmission, coaxially with the engine and the automatic transmission. A power transmission mechanism that increases or decreases the driving power of the front wheel is provided. The second motor is coupled to the power transmission mechanism without being coupled to the engine and the automatic transmission.

Abstract: In a chain belt having: plurality of link plates each provided with a pin hole; plurality of connecting pins to connect a part of the plurality of link plates in an endless annular form by being inserted into the pin holes across the part of the plurality of link plates in a state where the part of the plurality of link plates are overlapped; and a retainer pin welded to an end portion of the connecting pin and engaged with the link plate to prevent the link plate from coming off the connecting pin, the retainer pin is disposed in a posture in which an outer circumferential surface is in contact with an outer circumferential surface of the connecting pin, and a plurality of points on the outer circumferential surface of the retainer pin separated from each other in the circumferential direction are welded to the connecting pin.

Abstract: A variable transmission system for a vehicle is configured such that, when a magnitude of a hydraulic pressure detected by an hydraulic pressure sensor is a first predetermined value or more, a chord portion of a chain belt is pressed such that a raceway length of the chain belt is extended by at least a circumferential extension amount of the chain belt at the time when the magnitude of the hydraulic pressure is the first predetermined value. Hereby, it is possible to restrain the chain belt from coming off from a sheave even in a low vehicle speed range, at a low cost, without causing a fuel efficiency decrease and a driving torque decrease of the vehicle.

Abstract: A continuously variable transmission includes: a primary pulley; a secondary pulley; a power transmission member; a case; and a shield member. The shield member is disposed between an inner surface of the case and a first pulley that is one of the primary pulley and the secondary pulley, at a position on an opposite side of the first pulley from a second pulley that is another one of the primary pulley and the secondary pulley. The shield member includes a plate part that is configured to cover a part of an outer circumference of the first pulley, where the power transmission member is wound, such that the plate part intersects with a minimum width extension line and a maximum width extension line.

Abstract: A shaft supporting structure of belt-driven continuously variable transmission is provided. The shaft supporting structure comprises a bearing holding the rotary shaft (2) rotatably and a first fixing member (55) fixing the bearing (44) to the casing (20). A fixing point at which the bearing (44) is fixed to the casing (20) by the first fixing member (55) is situated within an area of the casing (20) axially corresponding to one of areas of the sheave (7, 8) defined by a diametrical line passing through an entrance point at which a pin (38) is pulled into a contact zone to the sheaves (7, 8) of a pulley (3), and a diametrical line passing through an exit point from which the pin (38) is withdrawn from the contact zone.

Abstract: A shaft supporting structure of a belt-driven continuously variable transmission for reducing a length of a shaft on which a torque cam is mounted is provided. A first bearing is interposed between an outer circumferential face of the rotary shaft and an inner circumferential face of the torque cam to support those members while allowing relative rotation therebetween. A second bearing is situated radially outside of the first bearing to support one of axial ends of the output member while allowing the output member to rotate relatively with a casing. A sealing member is fitted onto the torque cam to be interposed between an outer circumferential face of the torque cam and the second bearing.

Abstract: A control system for a belt-type continuously variable transmission capable of preventing deterioration in fuel economy. A friction coefficient ?2 in a radially outer region of the tapered face of the driven pulley 7 is smaller than a friction coefficient ?1 in a radially inner region, and the control system comprises a speed change region setting means that increases frequency of carrying out a speed change operation within the radially inner region in case the energy saving mode is selected.

Abstract: A belt-driven continuously variable transmission adapted to reduce a frictional resistance between the movable sheave and the rotary shaft. The pulley includes the fixed sheave rotated integrally with the rotary shaft, and the movable sheave engaged with the rotary shaft in a manner to slide axially and to be rotated integrally with the rotary shaft. The driving belt is applied to the belt groove formed between the movable sheave and the fixed shave to transmit torque. The transmission is provided with the a passage for delivering fluid to the engagement mechanism engaging the rotary shaft with the movable sheave while allowing relative axial movement therebetween.

Abstract: A belt-driven continuously variable transmission includes a drive pulley, a driven pulley and a driving belt. Each pulley is formed by a fixed sheave integrated with a rotary shaft and a movable sheave fitted onto the rotary shaft in a slidable manner. A belt groove holding a driving belt is formed individually between conical surfaces of the fixed sheave and the movable sheaves being opposed to each other. The belt-driven continuously variable transmission changes a speed ratio continuously by altering an effective diameter of the driving belt by varying the groove width. A non-metallic belt made of resin material is used as the driving belt, and a friction coefficient of a radially inner region of each conical surface of driven pulley is smaller than that in a radially outer region.