A carriage assembly includes a primary frame, a first idler wheel mounted to the primary frame, and a secondary frame pivotably mounted to the primary frame. The carriage assembly further includes an idler wheel assembly coupled to the secondary frame and movable with respect to the secondary frame along a longitudinal axis of the idler wheel assembly. The idler wheel assembly includes at least one second idler wheel and at least one third idler wheel mounted to the idler wheel assembly such that the second idler wheel is located between the first idler wheel and the third idler wheel. The first idler wheel is configured to pivot with the primary frame relative to the secondary frame, and the second idler wheel and the third idler wheel are configured to move with the idler wheel assembly relative to the secondary frame along the longitudinal axis of the idler wheel assembly.

A track assembly includes an elongated main frame supported for pivotal movement on a transverse axis and having opposite end portions supporting a set of end wheels. An endless flexible belt extends around the end wheels and has an upper run and a lower run for engaging the ground. A plurality of longitudinally spaced bogie wheels are positioned below the main frame and engage the lower run of the belt. The bogie wheels are carried by bogie frames supported for vertical movement and also for tilting movement relative to a plane defined by the axes of the end wheels. The bogie frames are urged or biased downwardly against the lower run of the belt by compression members extending from the main frame and preferably in the form of annular rubber spring members.

A track kit for a vehicle (2), having two track assemblies (1, 1), each track assembly having an endless track (5), a front idler wheel (8), an intermediate support member (6) with at least one track engaging element (7), a rear idler wheel (9), a drive wheel (10), at least one swing arm (11, 12) and a shock absorber connecting assembly (13, 14), wherein the endless track (5) has an external side featuring ground lugs (15) for ground engagement and an internal side featuring drive lugs (16) for engagement with the drive wheel (10), and the internal side is circumferentially trained around and in contact with the front idler wheel (8).

The invention relates to a tracked vehicle (V1, V2) comprising a vehicle body (20; 120), at least one track assembly (10) and a suspension device (S). Said track assembly (10) is arranged to be supported by said vehicle body (20; 120) by means of said suspension device (S). Said track assembly comprises a track support beam (12) for supporting a plurality of road wheels (16), an endless track (14) being disposed around said road wheels. Said suspension device (S) comprises a leaf spring arrangement (30; 130, 142, 144) having portions transversally arranged relative to the longitudinal extension of the vehicle. Said leaf spring arrangement comprises L-shaped leaf spring members (30; 130), each leaf spring member (30; 130) having a first portion (32; 132) attached to said vehicle body (20; 120), a second portion (34; 134) attached to said track support beam (12) and a transition portion (36; 136) there between, so that compressive and tensile stresses are located to said transition portion (36; 136) for generating a compressive action in said transition portion.

The invention relates to a tracked vehicle (V1, V2) comprising a vehicle body (20; 120), at least one track assembly (10) and a suspension device (S). Said track assembly (10) is arranged to be supported by said vehicle body (20; 120) by means of said suspension device (S). Said track assembly comprises a track support beam (12) for supporting a plurality of road wheels (16), an endless track (14) being disposed around said road wheels. Said suspension device (S) comprises a leaf spring arrangement (30; 130, 142, 144) having portions transversally arranged relative to the longitudinal extension of the vehicle. Said leaf spring arrangement comprises L-shaped leaf spring members (30; 130), each leaf spring member (30; 130) having a first portion (32; 132) attached to said vehicle body (20; 120), a second portion (34; 134) attached to said track support beam (12) and a transition portion (36; 136) there between, so that compressive and tensile stresses are located to said transition portion (36; 136) for generating a compressive action in said transition portion.

Tracked piste grooming vehicle for maintenance and shaping of snowy terrain, including a crawler chassis which includes, on each side of the chassis, a respective drive wheel, at least four running wheels and a tension wheel, all enclosed by a crawler chain, wherein each running wheel is mounted on a chassis frame in a pretensioned manner by a suspension. Each side of the chassis includes five respective running wheels, with the suspensions thereof having a different pretensioning distribution considered over a vehicle length.

An all-terrain vehicle configured to be propelled by an endless loop track and a suspension system therefore comprises first and second lower suspension rails pivotally attached to one another at a central pivot. First, second and third suspension supports are provided, each comprising a resilient element and a suspension strut, the suspension strut having an upper end pivotally connected to the frame and a lower end. The lower end of the suspension strut of the first suspension support is pivotally connected to the first lower suspension rail. The lower end of the suspension strut of the third suspension support is pivotally connected to the second lower suspension rail. The lower end of the suspension strut of the second suspension support is pivotally connected to the first lower suspension rail, the second lower suspension rail or the first and second lower suspension rails proximal the central pivot. This configuration advantageously provides improved driving dynamics for the vehicle when operated in rough terrain.

An all-terrain vehicle configured to be propelled by an endless loop track and a suspension system therefore comprises first and second lower suspension rails pivotally attached to one another at a central pivot. First, second and third suspension supports are provided, each comprising a resilient element and a suspension strut, the suspension strut having an upper end pivotally connected to the frame and a lower end. The lower end of the suspension strut of the first suspension support is pivotally connected to the first lower suspension rail. The lower end of the suspension strut of the third suspension support is pivotally connected to the second lower suspension rail. The lower end of the suspension strut of the second suspension support is pivotally connected to the first lower suspension rail, the second lower suspension rail or the first and second lower suspension rails proximal the central pivot. This configuration advantageously provides improved driving dynamics for the vehicle when operated in rough terrain.

A roller suspension system for a track-driven work vehicle may generally include a support beam and a resilient bushing configured to be coupled to the support beam. The resilient bushing may define a shaft opening. In addition, the system may include a roller wheel assembly having a roller wheel and a roller shaft. The roller wheel may be rotatable relative to the roller shaft. In addition, the roller shaft may be received within the shaft opening of the resilient bushing such that the roller shaft is coupled to the support beam via the resilient bushing.

A pivot assembly for connecting a ground-contacting wheel assembly to a frame member of a track system assembly has a base defining a first interlocking member, a resilient body structured for being received at least partially within the base and having a second interlocking member connectable to the first interlocking member, and an axle assembly configured for rotatably connecting the ground-contacting wheel assembly to the frame member, the axle assembly including a third interlocking member connectable to the second interlocking member. The resilient body is at least partially wrappable around the peripheral surface of the axle assembly. Upon deformation of the resilient body, the axle assembly is pivotally movable relative to the frame member of the track system assembly about at least one of a longitudinal axis and a vertical axis.