A powertrain mount assembly configured to connect a powertrain to a side rail of a vehicle frame structure, wherein the powertrain mount assembly comprises: a mounting bracket comprising a first side wall and a second side wall spaced apart from the first side wall, the mounting bracket being configured to receive a resilient member and a bracket arm between the first and second side walls, the bracket arm being connectable to the powertrain; and a first support bracket connectable to a surface of the side rail, wherein the first side wall of the mounting bracket is fastenable to the first support bracket and wherein the first support bracket is configured to be connected to the side rail at a location between the first and second side walls of the mounting bracket.

A roll restrictor for restraining movement of a vehicle powertrain relative to a vehicle sub-frame. The roll restrictor has a bracket for coupling to the sub-frame in the form of a generally U-shaped housing defining a central cavity. A link arm for coupling to the powertrain has a first end positioned within the cavity and extends through an opening in the bracket. A plurality of resilient elements are disposed within the cavity between the housing and the first end of the link arm to resist movement of the first end relative to the bracket.

Disclosed herein is a report on a drivetrain specifically designed to operate in conjunction with the Extreme-Travel Independent Suspension System. In a prior disclosure, we introduced a drivetrain concept derived from the unique configuration of the suspension system. The concept defines several elements, one element is a gearbox that is fabricated into the frame, the gearbox being called the reverse power coupler. Other elements of the concept include a differential mounted offset power coupler and differential housing assemblies. The drivetrain cooperates with the suspension configuration of upper and lower leading and trailing links thereby retaining the suspension system's fundamental propertieshandling quality like a double A-arm independent suspension system and travel and articulation capabilities similar to Ford's Twin I-Beam front suspension system. This report integrates the elements introduced in the prior disclosure with novel mechanistic features of the drivetrain. The features concentrate on the means by which power is transmitted from a differential housing to the wheels. Included in the features are the operations of the elements and the association of the elements with short and long axle shafts. The axle shafts serve as the principle conduits for transmitting power from one element to another.

The invention relates to a vehicle powertrain that includes an internal combustion engine, a transmission driving at least two wheels, and an intermediate unit connecting the engine and a transmission housing enclosing the transmission. The intermediate unit is configured to allow relative rotation between the engine and the transmission housing about an axis (X) that is colinear with an engine output shaft and a transmission input shaft. The arrangement prevents engine vibrations from being transmitted to the transmission, and prevents torque shock from the vehicle wheels from being transmitted to the engine.

A torque rod (1) has two elastic bushes (2, 3) to be mounted respectively to a vibration-generating side and a vibration-receiving side, and a connecting rod (4) connecting the two elastic bushes (2, 3). The actively controlled vibration cancellation means (5) is an actuator including: the shaft (5a) having two opposite ends mounted to the connecting rod (4) and extending in an axial direction of the connecting rod (4), the mass member (5b) shaped in a tube to surround the shaft (5a); a coil (5e) and a winding core (5f) fixed to the shaft (5a) in the tube-shaped mass member (5b); a permanent magnet (5d) mounted to an inner peripheral surface of the tube-shaped mass member (5b) or the shaft (5a), and a connecting member (5c) for connecting at least one end of the tube-shaped mass members (5b) to the shaft (5a).

An engine mount for a drive unit in a vehicle includes a bracket having first and second joining points for attachment of the bracket to the drive unit. A first mounting member connects the bracket to the drive unit in the first joining point along a first joining axis. An engine mount is arranged on a vehicle body and supports the drive unit via the bracket. A second mounting member connects the bracket to the drive unit in the second joining point along a second joining axis. The first and second joining axes extend at a slant to each other by an axis angle.

A first engine mount unit sharing no distributed load of a power unit includes: a power unit side bracket attached to the power unit; a vehicle body side bracket attached to a vehicle body; and a mount rubber provided between the power unit side bracket and the vehicle body side bracket. At attachment portions of the power unit side bracket and the vehicle body side bracket of the first engine mount unit, a bolt hole is provided in an inner cylinder part adhered to the mount rubber pressed into the power unit side bracket, to adjust variations in the height direction (H direction) of the vehicle, while bolt holes are provided in the vehicle body side bracket to adjust variations in the width direction (W direction) of the vehicle.

An object is to provide an industrial vehicle whereby it is possible to arrange an exhaust purifying apparatus in an efficient layout, and to achieve a high purifying performance. An industrial vehicle includes: a cargo loading device disposed on a front part of a vehicle; a counter weight disposed on a rear part of the vehicle; an engine housed in an engine room formed in front of the counter weight inside the vehicle; and an exhaust purifying device disposed inside the engine room and configured to purify exhaust gas of the engine.

Disclosed herein is a report on a drivetrain specifically designed to operate in conjunction with the Extreme-Travel Independent Suspension System. In a prior disclosure, we introduced a drivetrain concept derived from the unique configuration of the suspension system. The concept defines several elements, one element is a gearbox that is fabricated into the frame, the gearbox being called the reverse power coupler. Other elements of the concept include a differential mounted offset power coupler and differential housing assemblies. The drivetrain cooperates with the suspension configuration of upper and lower leading and trailing links thereby retaining the suspension system's fundamental properties--handling quality like a double A-arm independent suspension system and travel and articulation capabilities similar to Ford's Twin I-Beam front suspension system. This report integrates the elements introduced in the prior disclosure with novel mechanistic features of the drivetrain. The features concentrate on the means by which power is transmitted from a differential housing to the wheels. Included in the features are the operations of the elements and the association of the elements with short and long axle shafts. The axle shafts serve as the principle conduits for transmitting power from one element to another.

A vehicle engine mount structure includes a motor mount assembly, a motor bracket and a heat shield. The motor mount assembly has a first attachment part with a fastener receiving aperture, a vibration absorbing section and a second attachment part spaced apart from the first attachment part. The motor bracket has a first flange portion configured to support a vehicle engine and a second flange portion configured to attach to the second attachment part of the motor mount assembly. The heat shield is dimensioned to at least partially overlay the vibration absorbing section of the motor mount assembly and overlay the fastener receiving aperture with the heat shield being disposed between the motor mount assembly and the second flange portion of the motor bracket, and with the second flange portion of the motor bracket attached to the second attachment part of the motor mount assembly.