Systems and methods can prevent or reduce jerk during operation of a materials-handling vehicle that is unloaded or carrying a load. The vehicle comprises one or more user input devices configured to receive from an operator a request to perform an action and a processor. The processor is configured to determine, before performing the action requested by the operator, a force acting on the load carried by the materials-handling vehicle as a result of the action requested by the operator. The processor determines whether the force would result in a jerk if the action is performed as requested. If it is determined that the force would result in a jerk, the action is modified so as to reduce the force. If it is determined that the force would not result in a jerk, the materials-handling vehicle performs the action as requested by the operator without modification to reduce the force.

A system for protecting an operator on an aerial work platform from a crushing hazard includes a sensor, such as opto-electric sensor, positionable adjacent the control panel area. A control system is programmed to control operation of the driving components based on signals from the sensor.

A scissor lift includes a base, a platform, a lift assembly, and a linear actuator coupled to the lift assembly. The lift assembly includes a first support member pivotally coupled to a second support member and a third support member pivotally coupled to a fourth support member. The linear actuator includes a housing, a screw coupled to the housing, an extending member slidably coupled to the housing, and an electric motor coupled to the housing and configured to drive the screw to move the extending member relative to the housing. The housing includes a first mount coupled to the first support member and configured to rotate relative to the first support member about a first lateral axis. The extending member includes a second mount coupled to the third support member and configured to rotate relative to the third support member about a second lateral axis.

A working machine has a body, a ground-engaging propulsion structure supporting the body, an inclinable working arm pivotally connected to the body mounting a working implement at a distal end thereof, a drive arrangement configured to provide motive power, and a control system configured to determine a center of gravity of the working machine. The control system is configured to control or restrict a speed of movement of the working machine in response to the determined center of gravity.

A controller for use with a working machine includes a machine body and a load handling apparatus coupled to the machine body and moveable by a lift actuator and a sway actuator. The controller receives a signal representative of the position of the load handling apparatus and a signal representative of a stability of the working machine. The controller determines a movement range of the load handling apparatus about the sway axis and issues a signal for use by an element of the working machine. The controller restricts or prevents movement of the load handling apparatus outside of the permissible movement range relative to the lateral reference orientation, the permissible range being dependent on the signal representative of the position of the load handling apparatus with respect to the machine body or longitudinal reference orientation and the signal representative of the stability of the machine.

An electric linear actuator for a lift assembly of a scissor lift includes a housing having a first end defining an aperture and a second end opposite the first end, an extending member received within the aperture and slidably coupled to the housing, a screw coupled to the housing, and an electric motor coupled to the housing and configured to drive rotation of the screw to control movement of the extending member along an axis of extension. The housing includes a mount configured to pivotally couple the housing to the lift assembly of the scissor lift. The mount is offset from the second end of the housing along the axis of extension such that the mount is positioned between the first end and the second end of the housing.

A jacking machine includes a main body, a support leg, a ball screw assembly, a power device, a braking device, and a self-locking device. The self-locking device includes: a chainring surrounding and fixedly connected to the screw rod, a toothed claw corresponding to the chainring and rotatably connected to a side of the main body, a first elastic member providing force to the toothed claw, and an electric actuator. A control method thereof includes after receiving a jack-up command, controlling the braking device to leave a braking state, and controlling the toothed claw to switch to a disengaged state, controlling the power device to drive the support leg and the main body to move relatively, and after receiving a stop command, controlling the braking device to enter the braking state, and controlling the toothed claw to switch to an engaged state.

A jacking machine includes a main body, a support leg, a ball screw assembly, a power device, a braking device, and a self-locking device. The self-locking device includes: a chainring surrounding and fixedly connected to the screw rod, a toothed claw corresponding to the chainring and rotatably connected to a side of the main body, a first elastic member providing force to the toothed claw, and an electric actuator. A control method thereof includes after receiving a jack-up command, controlling the braking device to leave a braking state, and controlling the toothed claw to switch to a disengaged state, controlling the power device to drive the support leg and the main body to move relatively, and after receiving a stop command, controlling the braking device to enter the braking state, and controlling the toothed claw to switch to an engaged state.

A platform assembly includes a work platform including a platform floor and a safety rail extending from the platform floor to a rail height, and a primary sensor unit secured to the work platform and positioned adjacent one of the platform floor and the safety rail. The primary sensor unit is configured to monitor an area from the platform floor or from the safety rail to a space above the rail height and forward and aft of the work platform. The platform assembly enhances protection for an operator from sustained involuntary operation resulting in an impact with an obstruction or structure.

A process of providing dynamic industrial vehicle feedback comprises storing in memory, data identifying a vehicle-based event that characterizes an operation of an industrial vehicle. Further, the process comprises storing into memory, operation information collected from an electronic component on the industrial vehicle that is associated with the identified event. The collected operation information characterizes a current operating state of the industrial vehicle as the industrial vehicle is being operated. The process further comprises detecting that the event has occurred based upon the collected operation information and generating an output message based on the detected event and the collected operation information. The output message is then conveyed on the industrial vehicle.