A multi-material track pad for a continuous track assembly is disclosed. The track pad may include a body with a ground-engaging surface, wherein the body is formed of a metal material with a first hardness; a roller-engaging surface, wherein the roller-engaging surface is formed of a ceramic material with a second hardness that is greater than the first hardness; and a sprocket-engaging surface formed of the ceramic material.

A cladding structure and method for cladding machine components to inhibit crack propagation includes at least one set of primary bands, with each primary band being deposited adjacent to and abutting at least one other primary band, forming at least one inter-pass clad boundary, and at least one set of secondary bands deposited in a spaced configuration and oriented so as to intersect at least one inter-pass clad boundary.

A caterpillar device includes: a water film removing part which is provided in a power transmission member including chains, presses and removes a water film between an attachment object as a magnetic material, and the power transmission member with a magnetic force, and attaches the power transmission member to the attachment object to secure a frictional force; and an apparatus body magnet attachment part which is connected to the power transmission member and attaches the body of the apparatus to the attachment object.

A caterpillar device includes: a water film removing part which is provided in a power transmission member including chains, presses and removes a water film between an attachment object as a magnetic material, and the power transmission member with a magnetic force, and attaches the power transmission member to the attachment object to secure a frictional force; and an apparatus body magnet attachment part which is connected to the power transmission member and attaches the body of the apparatus to the attachment object.

A track shoe assembly is described that comprises a drive lug part and a track shoe body including a drive lug cavity configured to receive the drive lug part. The drive lug part has at least one lug portion protruding in a first direction, and at least one 5 supporting protrusion extending in a direction substantially opposite to the first direction. The at least one supporting protrusion is configured to be receivable in a drive lug cavity formed in a track shoe such that a load applied to the drive lug part is at least partially transferred to the track shoe.

A track link includes a tread surface, a shoe surface, a communicating part, and a seat formation part. The tread surface comes into contact with a roller for an undercarriage. The shoe surface is disposed on an opposite side from the tread surface. A track shoe is attachable to the shoe surface. The communicating part is disposed between the shoe and tread surfaces. The communicating part passes through the track link in a width direction that is perpendicular to a linking direction, and allows side faces of the track link to communicate in the width direction. The seat formation part is formed on a shoe surface side of the communicating part. A through-hole passes through from the shoe surface to the seat formation part, and a bolt member is disposable in the through-hole. A number track links in a loop are usable in a track of a work vehicle.

A track link includes a tread surface, a shoe surface, a communicating part, and a seat formation part. The tread surface comes into contact with a roller for an undercarriage. The shoe surface is disposed on an opposite side from the tread surface. A track shoe is attachable to the shoe surface. The communicating part is disposed between the shoe and tread surfaces. The communicating part passes through the track link in a width direction that is perpendicular to a linking direction, and allows side faces of the track link to communicate in the width direction. The seat formation part is formed on a shoe surface side of the communicating part. A through-hole passes through from the shoe surface to the seat formation part, and a bolt member is disposable in the through-hole. A number track links in a loop are usable in a track of a work vehicle.

Provided is an elastic crawler and an elastic crawler device capable of achieving both low fuel consumption and excellent ride comfort. The elastic crawler comprises: a main body; cores respectively having a pair of wings and being embedded in a circumferential direction; a track roller rolling surface formed on an inner circumferential surface of the main body; a recess formed on the inner circumferential surface in a manner extending from the track roller rolling surface toward a widthwise outer side; lugs formed on an outer circumferential surface of the main body, the lugs respectively extending in a width direction between the cores from one end overlapping the track roller rolling surface in a thickness direction toward the other end overlapping a part in which the wings of the cores are embedded in the thickness direction. The elastic crawler device comprises the elastic crawler, a sprocket and a track roller.

A self-propelled module for oversize loads includes two ground movement assemblies with oil-pressure controlled actuation; a transverse rocker arranged between the movement assemblies, which are coupled thereto independently; oil-pressure controlled suspension elements, arranged on corresponding oscillating supports coupled to the transverse rocker; and a load-bearing frame, supported by the oil-pressure controlled suspension elements. The load-bearing frame includes an oil-pressure controlled circuit adapted to serve the ground movement assemblies and the suspension elements. The module further includes a rotary distribution unit, having a vertical axis, mounted on the load-bearing frame for supplying the ground movement assemblies and the oil-pressure controlled suspension elements, a first part of the rotary distribution unit being fixed to the load-bearing frame, and a second part being free to rotate about the vertical of the resting surface with respect to the load-bearing frame.

A self-propelled module for oversize loads includes two ground movement assemblies with oil-pressure controlled actuation; a transverse rocker arranged between the movement assemblies, which are coupled thereto independently; oil-pressure controlled suspension elements, arranged on corresponding oscillating supports coupled to the transverse rocker; and a load-bearing frame, supported by the oil-pressure controlled suspension elements. The load-bearing frame includes an oil-pressure controlled circuit adapted to serve the ground movement assemblies and the suspension elements. The module further includes a rotary distribution unit, having a vertical axis, mounted on the load-bearing frame for supplying the ground movement assemblies and the oil-pressure controlled suspension elements, a first part of the rotary distribution unit being fixed to the load-bearing frame, and a second part being free to rotate about the vertical of the resting surface with respect to the load-bearing frame.