One general aspect includes a tethered temperature sensor (300) for use within a vehicle track (100). The tethered temperature sensor (300) includes one or more sensors (308) for measuring temperature located in a high strain and high temperature region (104) of the vehicle track (100). The sensor also includes circuitry (402) configured to control and/or monitor the one or more sensors and located in a low strain and low temperature region (102) of the vehicle track (100). The sensor also includes a housing (406) to contain the circuitry. The sensor also includes an encapsulating material (408) that fills an interior of the housing (406).

One general aspect includes a tethered temperature sensor (300) for use within a vehicle track (100). The tethered temperature sensor (300) includes one or more sensors (308) for measuring temperature located in a high strain and high temperature region (104) of the vehicle track (100). The sensor also includes circuitry (402) configured to control and/or monitor the one or more sensors and located in a low strain and low temperature region (102) of the vehicle track (100). The sensor also includes a housing (406) to contain the circuitry. The sensor also includes an encapsulating material (408) that fills an interior of the housing (406).

A wheel of a track system for traction of a vehicle (e.g., an agricultural vehicle) may be configured to protect against (e.g., prevent) accumulation of unwanted ground matter, such as mud, debris, water, etc., within the wheel, while enhancing visual appearance of the wheel. This may help to avoid or minimize mud buildup that may otherwise need to be drilled out before removing the wheel (e.g., for replacement or maintenance) and/or rust that may otherwise arise.

A wheel of a track system for traction of a vehicle (e.g., an agricultural vehicle) may be configured to protect against (e.g., prevent) accumulation of unwanted ground matter, such as mud, debris, water, etc., within the wheel, while enhancing visual appearance of the wheel. This may help to avoid or minimize mud buildup that may otherwise need to be drilled out before removing the wheel (e.g., for replacement or maintenance) and/or rust that may otherwise arise.

A track assembly for a vehicle has a frame; a drive wheel rotatably mounted to the frame; an idler wheel mount pivotally connected to the frame, the idler wheel mount being selectively pivotable between an operating position and a released position; a lock selectively locking the idler wheel mount in the operating position; an idler wheel rotationally connected to the idler wheel mount, the idler wheel being pivotable with the idler wheel mount; and an endless track driven by the drive wheel around the frame. In the operating position of the idler wheel mount, the idler wheel tensions the endless track. Pivoting the idler wheel mount from the operating position to the released position releases at least some tension from the endless track. A vehicle having the track assembly and a method for installing an endless track having derailed from other components of a track assembly are also disclosed.

A track assembly for a vehicle has a frame; a drive wheel rotatably mounted to the frame; an idler wheel mount pivotally connected to the frame, the idler wheel mount being selectively pivotable between an operating position and a released position; a lock selectively locking the idler wheel mount in the operating position; an idler wheel rotationally connected to the idler wheel mount, the idler wheel being pivotable with the idler wheel mount; and an endless track driven by the drive wheel around the frame. In the operating position of the idler wheel mount, the idler wheel tensions the endless track. Pivoting the idler wheel mount from the operating position to the released position releases at least some tension from the endless track. A vehicle having the track assembly and a method for installing an endless track having derailed from other components of a track assembly are also disclosed.

A system may include a device. The device may be configured to receive machine vibration data identifying a measure of vibration of a machine. The vibration, of the machine, may be caused by a combination of first vibration caused by a motion of components of an undercarriage of the machine and second vibration that is unrelated to the first vibration. The device may be configured to identify a segment, of the machine vibration data, corresponding to the first vibration; transform the segment, using a Fast Fourier Transform (FFT), into a signal in a frequency domain; and analyze the signal to identify a signature spectrum associated with the motion of components. The device may be configured to predict, based on the signature spectrum, an amount of wear of the components. The device may be configured to cause an action to be performed based on the amount of wear of the components.

A link assembly for a machine is disclosed herein. The link assembly includes a first master link portion, a full track link, and a plug. The full track link is coupled to the first master link portion. The plug is positioned within the full track link and adjacent to the first master link portion. The plug is positioned and shaped to prevent the rotational movement of the first master link portion.

A link assembly for a machine is disclosed herein. The link assembly includes a first master link portion, a full track link, and a plug. The full track link is coupled to the first master link portion. The plug is positioned within the full track link and adjacent to the first master link portion. The plug is positioned and shaped to prevent the rotational movement of the first master link portion.

A track shoe includes a base plate, a grouser extending from the base plate, and at least one white iron member. At least a portion of the grouser includes a substantially martensitic structure. The at least one white iron member is fixed to a portion of the grouser.