Endless elastomeric tracks include guide lugs disposed on an inner circumference, rubber tread lugs disposed on an outer circumference, and a thin band continuously extending in the circumferential direction which is disposed adjacent the outer circumference. The thin band has an exterior peripheral surface and an inner peripheral surface, and at least one galvanized wire ply is disposed between the exterior peripheral surface and an inner peripheral surface. The endless track further includes at least one primary cable of galvanized steel circumferentially reinforcing the thin band. In some aspects, the at least one galvanized wire ply includes a plurality of galvanized wires having a diameter of from about 0.15 mm to about 1.5 mm, from about 0.175 mm to about 1.3 mm, from about 0.20 mm to about 1.25 mm, from about 0.22 mm to about 1.2 mm, or even from about 0.25 mm to about 1.1 mm.

A track system for use with a vehicle includes an attachment assembly connectable to the chassis of the vehicle having a first pivot extending vertically and defining a yaw pivot axis of the track system, and a second pivot extending laterally and defining a pitch pivot axis of the track system. A frame assembly is disposed laterally outwardly from the attachment assembly and connected thereto. The frame assembly includes at least one wheel-bearing frame member. The track system further includes at least one actuator connected between the attachment assembly and the frame assembly for pivoting the frame assembly about the yaw pivot axis, a leading idler wheel assembly at least indirectly connected to the at least one wheel-bearing frame member, a trailing idler wheel assembly at least indirectly connected to the at least one wheel-bearing frame member, at least one support wheel assembly, and an endless track.

A drive wheel for a track system having an endless track that has first, second, and third drive wheel engagers is disclosed. The drive wheel has a hub, a body, a rim, a plurality of first, second and third track engagers radially disposed on the rim. Each of the plurality of second track engagers are operationally aligned with one of the plurality of first track engagers. The plurality of third track engagers are on at least one lateral side of the plurality of first track engagers. The plurality of first, second and third track engagers are configured to, respectively, driveably engage with a first, second, and third drive wheel engagers of the endless track. An endless track and a track system are also disclosed.

A traction device for an elastomeric track comprises a first bracket comprising a first portion comprising a tapered surface and a second portion configured to be removably coupled to the first portion to define a U-shaped channel configured to receive at least a portion of an elastomeric track, a first chain coupled to the first bracket at a first end of the first chain, a second bracket coupled to a second end of first chain opposite the first bracket, and a plate coupled to the first chain between the first bracket and the second bracket, the plate configured to substantially prevent the first chain from entering the recesses of the elastomeric track. Related traction devices and methods of attaching a traction device to an elastomeric track are also disclosed.

A track for a track vehicle has sensor-receiving cavities disposed therein. Removeable sensors are placed in the sensor-receiving cavities for sensing characteristics of the track during operation.

A track for traction of a vehicle (e.g., a snowmobile), in which the track is studded, i.e., comprises studs, to enhance its traction, including to optimize acceleration, control, and/or braking of the vehicle, such as, for example, by increasing engagement of the studs with a ground on which the vehicle travels (e.g., increasing their number and/or exposure) and/or improving retention of the studs in the track (e.g., better orienting and/or anchoring them), while being lightweight, reducing noise, and/or withstanding high speeds.

A carriage assembly for a continuous track drive system can include a plurality of road wheels, a pivotable idler wheel, a drive wheel, a continuous track extending around the plurality of road wheels, the pivotable idler wheel, and the drive wheel, and a tensioning system coupled to the idler wheel. The tensioning system can include an actuator and a biasing member. The tensioning system can be configured such that when the continuous track is driven in a first direction the actuator is inactive and the biasing member maintains tension in the continuous track, and when the continuous track is driven in a second direction the actuator is active and applies force to the pivotable idler wheel to maintain tension in the continuous track.

A track for traction of a vehicle, such as an agricultural vehicle, an industrial vehicle (e.g., a construction vehicle), a military vehicle, or another off-road vehicle, is provided. The track comprises a ground-engaging outer surface for engaging the ground and a plurality of traction projections projecting from the ground-engaging outer surface and distributed in a longitudinal direction of the track. The traction projections may be designed to enhance their resistance to deterioration during use. For example, a blowout resistance of each traction projection may be enhanced to prevent or at least reduce a potential for blowout of the traction projection under repeated loads which may induce heat buildup within it. Also, a wear resistance of the traction projection may be enhanced such that the traction projection wears less rapidly. A system for protecting a track against potential occurrence of blowout is also provided.

A vehicle (e.g., an agricultural vehicle or other off-road vehicle) comprising a track system can be monitored to obtain information regarding the vehicle, including information regarding the track system, such as one or more parameters (e.g., a temperature, a pressure, an acceleration, an identifier, etc.) of the track system and/or one or more characteristics of an environment of the track system (e.g., a compliance, a profile, a soil moisture level, etc. of the ground beneath the track system), which can be used for various purposes, such as, for example, to: convey the information to a user (e.g., an operator of the vehicle); control the vehicle (e.g., a speed of the vehicle, operation of a work implement, etc.); transmit the information to a remote party (e.g., a provider such as a manufacturer or distributor of the track system and/or of the vehicle; a supplier of a substance such as fertilizer used where the vehicle is located; etc.); control equipment (e.g., an irrigation system, a fertilizing system, etc.) external to the vehicle; etc.

A track roller unit for an agricultural working machine has at least one first guide roller and one second guide roller. The first guide roller is mounted on a first supporting arm and the second guide roller is mounted on a second supporting arm. At least one support roller is situated between the guide rollers, and a track belt wraps around the guide rollers and the at least one support roller. A hydropneumatic damping element is assigned to at least one guide roller and/or one support roller. At least one regulated restrictor device, which is assigned to a damping element, is provided and is designed in such a way that its flow resistance is adjustable during the operation of the track roller unit.