A person-lifting and fall-protection vehicle includes a carrier vehicle having a two-direction vehicle or a multi-direction vehicle, and a person-lifting device having a telescopic boom and a work cage.

A vehicle apparatus has a chassis with a plurality of rear wheels (e.g., flotation axel wheels) and a plurality of front wheels (e.g., drive/steer wheels) coupled thereto. A scissor lift assembly may couple to the chassis and hoist and lower a man basket. The man basket has hinged sides that may be released to a horizontal position, thereby extending the working platform of a user. A rotatable pedestal allows a central tie-off spot for added safety and efficacy.

A safety latch system includes a mount, a pawl member, a ratchet member, and a release assembly. The mount is mountable on a housing of a piston. The pawl member is coupled to the mount. The pawl member includes a pawl. The ratchet member has a first sidewall that includes a first connecting portion that is connectable to an end portion of a piston rod of the piston. The first sidewall includes a teeth portion, which is configured to engage with the pawl. The release assembly is configured to provide an engaged state between the pawl member and the ratchet member. The release assembly is also configured to provide a disengaged state between the pawl member and the ratchet member. When in the engaged state, the pawl member is engaged with the ratchet member such that the safety latch system is configured to provide (i) an unlocked state in which the ratchet member is movable relative to the pawl member as the piston rod advances outward from the housing and (ii) a locked state in which the pawl member is configured to lock into a depression between adjacent teeth of the ratchet member to stop the piston rod from moving towards the housing. When in the disengaged state, the pawl member is disengaged from the ratchet member to permit the piston rod to advance outward from the housing and permit the piston rod to retract towards the housing.

A lift device includes a base, a platform configured to support an operator, and a scissor assembly coupling the base to the platform. The scissor assembly includes an actuator configured to extend and retract the scissor assembly to move the platform between a fully raised position and a fully lowered position, a first scissor arm pivotally coupled to a second scissor arm, and a prop pivotally coupled to the first scissor arm such that the prop rotates about a lateral axis. The prop is configured to selectively engage an engagement surface defined by at least one of the second scissor arm and a protrusion coupled to the second scissor arm, thereby preventing the platform from reaching the fully lowered position.

A machine includes a base, a lift assembly, a first wireless transceiver, a plurality of second wireless transceivers, and a processing circuit. The lift assembly is coupled to and repositionable relative to the base. The first wireless transceiver is coupled to a portion or component of the lift assembly. The first wireless transceiver is configured to transmit a first wireless signal. The plurality of second wireless transceivers are coupled to the base. The plurality of second wireless transceivers are configured to detect the first wireless signal and transmit a plurality of second wireless signals in response to detecting the first wireless signal. The first wireless transceiver is configured to detect the plurality of second wireless signals. The processing circuit is communicably coupled to the first wireless transceiver. The processing circuit is configured to determine a position of the portion or component based on information acquired from the first wireless transceiver.

A lift vehicle comprises a base having a plurality of wheels, a battery arranged within the base, a drive motor powered by the battery and configured to drive at least one of the plurality of wheels and propel the base, a retractable lift including a first end coupled to the base and being movable between an extended position and a retracted position, a work platform supported by a second end of the retractable lift, and a linear actuator having a lift motor with a rotor. The lift motor is powered by the battery, and the linear actuator is coupled to the retractable lift so that rotation of the rotor moves the retractable lift between the extended position and the retracted position. The lift vehicle further includes an electromagnetic brake coupled to a first side of the lift motor.

The present invention relates to the field of engineering machinery, and discloses a method and an apparatus for judging the safety of an operation which may be performed by a boom and an engineering machinery, the method including: acquiring parameters for each arm in the boom, wherein the parameters comprise an inclination angle, an arm length, and mass; determining, based on the acquired parameters, a position of the full center of mass of the boom and a position of the combined center of mass from an operating arm to a terminal arm; determining a safety judging basis direction vector based on the position of the full center of mass and the position of the combined center of mass; and judging the safety of an operation which may be performed on the operating arm based on the safety judging basis direction vector. Therefore, it is realized to judge the safety of the operation which may be performed on the operating arm, and the operating arm has not been operated at the time of judging the safety, so the judgment of the safety of the operation which may be performed on the operating arm is pre-judgment, that is, the safety of the operation which is about to be performed on the operating arm is pre-judged, and the predictability is realized.

Sensors on an aerial lift device determine the number of occupants in and occupant portion of the aerial lift device. Prior to permitting the occupant portion to rise up off the ground, the system checks the engagement of safety harnesses to verify that the number of engaged safety harnesses matches the number of occupants in the occupant portion of the aerial lift. If the number matches, operation of the aerial lift may be enabled and the occupant portion deployed. If the number does not match, an alarm is sounded and deployment of the occupant portion may be disabled. With pre-deployment safety testing, and no occupants in the occupant portion, the occupant portion may be deployed to verify all operational status of the occupant portion with no occupants. The system may further create a data log to verify the time and successful pre-deployment safety check.

A safety latch system includes a mount, a pawl member, a ratchet member, and a release assembly. The mount is mountable on a housing of a piston. The pawl member is coupled to the mount. The pawl member includes a pawl. The ratchet member has a first sidewall that includes a first connecting portion that is connectable to an end portion of a piston rod of the piston. The first sidewall includes a teeth portion, which is configured to engage with the pawl. The release assembly is configured to provide an engaged state between the pawl member and the ratchet member. The release assembly is also configured to provide a disengaged state between the pawl member and the ratchet member. When in the engaged state, the pawl member is engaged with the ratchet member such that the safety latch system is configured to provide (i) an unlocked state in which the ratchet member is movable relative to the pawl member as the piston rod advances outward from the housing and (ii) a locked state in which the pawl member is configured to lock into a depression between adjacent teeth of the ratchet member to stop the piston rod from moving towards the housing. When in the disengaged state, the pawl member is disengaged from the ratchet member to permit the piston rod to advance outward from the housing and permit the piston rod to retract towards the housing.

A flip door assembly includes a flip door and an interlock that controls whether the flip door may be opened. A worker safety system in one embodiment includes a work stand, a safety barrier, and a flip door assembly. The flip door assembly selectively engages with a keyed portion of the safety barrier to prevent access to a defined area by a worker. The flip door assembly includes a flip door having a top surface that is substantially planar to a top surface of the work stand when closed, and substantially non-planar to the top surface of the work stand when open. The flip door assembly further includes an interlock that prevents the flip door from opening when the keyed portion of the safety barrier is disengaged from the interlock, and allows the flip door to open when the keyed portion of the safety barrier is engaged with the interlock.