A motor drive assembly for selective rail or track operation of an excavators or other mobile platform via a source of hydraulic pressure. The motor drive assembly may include one or more drive arm assemblies mounted at ends of the mobile platform underbody, with the drive arm assembly including a motor, a gearbox, and hydraulic features for operation, including a counterbalance valve assembly, as well as improved gearbox and coupler elements operable therewith. The counterbalance valve assembly may include a cross-port relief valve and may have a first hydraulic operating circuit and a second hydraulic operating circuit. The first hydraulic operating circuit may communicate hydraulic pressure to the gearbox to enable movement of the mobile platform, and the second hydraulic operating circuit may prevent undesired communication of hydraulic pressure to the gearbox.

A depth guidance system for a work vehicle can be provided. In one example, the depth guidance system can include a depth sensor for detecting a depth of a work tool coupled to the work vehicle. The depth guidance system can include a first indicator light configured to illuminate in a first color indicating that the work tool is above a target depth-range. The depth guidance system can also include a second indicator light configured to illuminate in a second color indicating that the work tool is within the target depth-range. The depth guidance system can receive sensor signals from the depth sensor indicating that the work tool is at various depths and responsively activate a corresponding one of the first indicator light or the second indicator light for each depth among the various depths of the work tool.

The present disclosure relates to a safety system for a construction machine, and the safety system for a construction machine according to the exemplary embodiment of the present disclosure includes: a pilot pump which supplies a pilot working fluid; multiple spools which are operated by the pilot working fluid to control a supply of a main working fluid and each have a signal unit formed in one region thereof; a signal line which sequentially connects the pilot pump and the signal units of the multiple spools and discharges the pilot working fluid, which is supplied by the pilot pump, to a hydraulic tank; and a pressure sensor which measures pressure in the signal line.

A system for preventing rolling-over of vehicles is disclosed: The system may include: at least one camera attached to a portion of the vehicle such that images capture by the camera include a portion of the vehicle and a portion of a surrounding area; a communication module; and a controller configured to: receive from the camera, via the communication module, at least one image; receive data related to the parameters of the vehicle; calculate a relative position between the vehicle and a ground based on the received at least one image; calculate a location of the vehicle's center of gravity based on the received at least one image and the data related to the parameters of the vehicle; and determine a probability of rolling-over the vehicle based on the calculated center of gravity and the relative position.

Embodiments of the present disclosure relate to a device for detecting a rotary angle and an excavator. The device is used for the excavator. The device can include: a synchronous belt, arranged around a rotating shaft of a slewing mechanism of the excavator, a tooth-shaped surface of the synchronous belt being away from a surface of the rotating shaft; a transmission part, engaged with the tooth-shaped surface of the synchronous belt and arranged on a supporting base; an angle detection part, in transmission connection to the transmission part; and the supporting base, connected to a chassis of the excavator.

A system for proactively controlling rimpull limit of a machine includes a hydraulic system having a lift cylinder to move an implement; a lift cylinder pressure sensor that senses a hydraulic pressure of the lift cylinder and responsively produces a lift cylinder pressure signal; and a controller in operable communication with the power train and the lift cylinder pressure sensor. The controller is configured to receive the lift cylinder pressure signal; determine the rimpull limit based at least in part upon the lift cylinder pressure signal; and adjust the torque of the power train to the rimpull limit.

The present disclosure discloses a trunnion mount for mounting an engine, in particular a combustion engine, to a chassis, comprising a support element rigidly connected and/or connectable to the engine having a ring portion with an outer bearing surface, which may be arranged concentrically around the crankshaft; a female support having an inner bearing surface for surrounding the bearing surface of the support element, the female support forming the link between the chassis and the engine; and a rubber bearing arranged between the inner bearing surface of the female support and the outer bearing surface of the support element. In one or more examples, the trunnion mount includes a rubber bearing that is directly vulcanized on at least one of the bearing surfaces and/or wherein the ring portion is formed as a separate element from a mounting portion of the support element and connectable thereto via axial screws.

A trunnion mount for mounting an engine to a chassis. A support element fixedly connected and/or connectable to the engine and having a ring portion with an outer bearing surface that is arranged concentrically around the crankshaft of the engine. A shelf having an inner bearing surface for surrounding the outer bearing surface of the support element. The shelf forming the link between the chassis and the engine. A rubber bearing arranged between the inner bearing surface of the shelf and the outer bearing surface of the support element. The trunnion mount is characterized in that the rubber bearing is axially press-fitted on the outer bearing surface of the support element.

To make a reserve tank be hardly affected by the heat of an engine. An engine room (5) is totally covered by an exterior cover (9) including openings (44) at the upper surface, and includes in the inside thereof an engine (13), a radiator (24), a cooling fan (20) for sucking external air and cooling the radiator, and a reserve tank (30) for storing cooling water of the engine. The reserve tank (30) is disposed at a position above the engine (13) and facing the openings (44) and a position on the upstream side of the flow of the air with respect to the openings (44).

A ranging radio relative machine positioning system for a first mobile machine and a second mobile machine is provided. The first mobile machine includes a platform rotatable relative to ground-engaging elements of the first mobile machine. A first set of ranging radios and at least one sensor are configured for attachment to the first mobile machine, and a second set of ranging radios are configured for attachment to the second mobile machine. The system also includes a controller programmed to identify a ground spotting location relative to the first mobile machine, track movement of the first mobile machine relative to the ground spotting location using the sensor to arrive at an offset, and provide a location, or pose, of the second mobile machine relative to the ground spotting location using the first and second sets of ranging radios and the offset.