A tip-over prevention system for vehicle, including a tilt detector operably coupled to a rear axle of the vehicle. The tilt detector is configured to detect a current tilt. A tilt controller is placed in electronic communication with the tilt detector and the tilt controller is placed in electronic communication with a braking controller that is configured to activate a braking system of the vehicle. The tilt controller is configured to determine if the current tilt exceeds a preset tilt threshold. In response to the current tilt exceeding the preset tilt threshold, the tilt controller is configured to signal the braking controller to activate the braking system of the vehicle.

A work implement tilt control system for a tracked vehicle having a frame and a work implement mounted to the frame, the system comprising: a lifting unit configured to controllably raise or lower at least part of the work implement; an input device actionable by a first and second types of external actions associated with raising or lowering of the work implement; and a vehicle computer configured to send a signal to the lifting unit to carry out a lowering cycle of the work implement in case the vehicle computer determines that a set of conditions has been met. In some cases, the set of conditions includes: (i) a movement characteristic of the tracked vehicle exceeds a threshold; and (ii) the input device has been actioned by the first type of external action since carrying out the most recent lowering cycle of the work implement.

A material type identifier identifies a type of material loaded into a dump truck. When the dump truck is unloaded, a flow rate identification system identifies a flow rate of material exiting the dump truck. A flow rate controller automatically controls the tailgate actuator based on a desired flow rate of material exiting the dump body of the dump truck.

A tip-over prevention system for dumping vehicles includes a tilt detector operably coupled to one of a cargo body and a chassis of a dumping vehicle. At least a portion of the cargo body is configured to be raised by a piston, and the tilt detector is configured to detect a current tilt. The system includes a fluid release valve placed in fluid communication with the piston which is activated in response to the tilt detector detecting a current tilt that exceeds a preset tilt limit. Activation of the fluid release valve releases a pressure in the piston causing the cargo body of the vehicle to lower.

An energy-dissipative pneumatic cushioning system for cushioning heavy loads includes (i) one or more support members that extend beneath at least a portion of at least one pneumatic cushioning element and (ii) at least one connector assembly that communicatively couple the at least one pneumatic cushioning element to a gas supply unit and optionally at least one gas reservoir. The at least one gas reservoir is capable of accepting at least a portion of gas from the at least one pneumatic cushioning element under a force of a load. The at least one connector assembly is further operable to allow a return of at least a portion of the gas to the at least one pneumatic cushioning element upon reduction of at least a portion of the force of the load.

A haul truck dump tray with a pneumatic shock absorption system is provided. The haul truck dump tray includes a first longitudinal body portion and a second longitudinal body portion joined along a center line by an interposing elastomeric link extending along the center line and bonded to and between them. The haul truck dump tray includes a topside support member joined along the center line by the interposing elastomeric link to the first longitudinal body portion and the second longitudinal body portion. The haul truck dump tray includes a bottomside support member joined along the center line by the interposing elastomeric link to the first longitudinal body portion and the second longitudinal body portion. The resulting haul truck dump tray has improved weight, strength, and durability characteristics.

A system for detecting distribution of a weight of a payload in a dump body of a vehicle includes first sensors, second sensors, and a controller. The dump body is pivotable about pins to be selectively seated and titled to a frame of the vehicle. The first sensors are arranged between the dump body and the frame, and detect components of the weight of the payload exerted through the dump body when the dump body is seated relative to the frame. The second sensors are arranged correspondingly within the pins, and detect components of the weight of the payload exerted through the dump body. The controller determines a status of payload distribution in the dump body based on the component of the weight of the payload detected by the first sensors and second sensors, and generate a notification to indicate the status of payload distribution.

A haulage vehicle includes a body, a load measurement device that measures a mounted load value of the body, a traveling electric motor, and a travel control device that outputs an electric motor command value, the travel control device sets a backward movement limiting set value to ON when it is determined that the haulage vehicle is in execution of either loading work or dumping work, and sets the backward movement limiting set value to OFF when a forward position signal and an accelerator pedal command value are inputted, an electric motor command value formed of a backward movement limiting command value is outputted to the traveling electric motor when the backward movement limiting set value is ON, and an electric motor command value formed of a normal command value is outputted to the traveling electric motor when the backward movement limiting set value is OFF.

An oscillation brake system and method is disclosed for a vehicle having front and rear vehicle sections coupled with an oscillation joint that allows rotation about an oscillation axis. The system includes front and rear brake sections rigidly coupled to the front and rear vehicle sections, respectively. The rear vehicle section has multiple degrees of freedom of movement relative to front vehicle section. When the oscillation brake is activated the front brake section engages the rear brake section to increase resistance against or prevent rotation about the oscillation axis. The system can also include sensors, and a controller that activates the system based on the sensor readings. The sensors can include accelerometers, pressure, position, speed or other sensors. The oscillation brake can include a hub splined to separator plates and a housing splined to friction plates, where the oscillation brake is activated to force the separator and friction plates together.

A method for determining stability of a vehicle having a load suspended from the vehicle is provided. The method can include obtaining measurements from a plurality of sensors positioned on the vehicle, obtaining a measurement from a vehicle accelerometer operative to determine an inclination of the vehicle, determining a position of the load suspended from the vehicle, determining a slung load of the load suspended from the vehicle, using the determined slung load and the determined position of the load suspended from the vehicle, determining tipping moments acting on the vehicle, determining righting moments acting on the vehicle and determining a tipping stability based on the determined tipping moments and determined righting moments.