A lift device includes a lift apparatus and a base assembly. The lift apparatus is configured to raise and lower an implement assembly. The base assembly is configured to support the lift apparatus. The base assembly includes a deployable operator station transitionable between a deployed position and a stowed position. In the deployed position, the deployable operator station is configured to provide a seating and control arrangement for an operator. In the stowed position, the deployable operator station is substantially sealed from an external environment to limit access to the deployable operator station.

A safety apparatus configured for attachment to a manlift and configured to prevent objects falling over the side of the manlift from striking objects and people beneath the manlift. One embodiment includes a frame configured to support netting that is disposed on the platform of an open-sided manlift and angled outward to intercept objects falling vertically outside the surface area of the platform. Another embodiment includes a frame that extends beyond the lip of a dosed-sided manlift and contains netting configured to catch objects falling outside of the surface area of the closed-sided manlift.

A local fleet connectivity system includes a plurality of machines disposed at a location. Each of the plurality of machines include an implement and a prime mover configured to drive the implement. The system includes a connectivity hub configured to establish, via a connectivity module, a connection with the plurality of machines. The connectivity hub is configured to establish a connection with at least one remote server. The connectivity hub is configured to exchange data between the plurality of machines and the at least one remote server. The data flows through the connectivity hub.

A lift device includes a chassis, a platform configured to support a user, a lift assembly coupling the platform to the chassis, an actuator configured to at least one of (a) move the platform relative to the chassis or (b) propel the chassis, a sensor assembly, and a controller. The sensor assembly includes a rod including a first end portion coupled to the platform and a second end portion opposite the first end portion, a housing defining an aperture sized to receive the second end portion of the rod, and a sensor coupled to the housing and configured to provide a signal in response to the second end portion of the rod exiting the aperture. The controller is operatively coupled to the sensor and the actuator and configured to control the actuator in response to receiving the signal from the sensor.

A lift device includes a chassis, a platform configured to support a user, a lift assembly coupling the platform to the chassis, an actuator configured to at least one of (a) move the platform relative to the chassis or (b) propel the chassis, a sensor assembly, and a controller. The sensor assembly includes a bar including a first end portion coupled to the platform and a second end portion opposite the first end portion. The sensor assembly further includes a sensor coupled to the platform and configured to provide a signal in response to the second end portion of the bar contacting the sensor. The controller is operatively coupled to the sensor and the actuator and configured to control the actuator based on the signal from the sensor.

A lift machine includes a base having a first end and a second end, a first assembly, and a second assembly. The first end has first and second pivot points defining a first lateral axis. The second end has third and fourth pivot points defining a second lateral axis. The first assembly is pivotably coupled to the first and second pivot points. The first assembly extends away from the base in a first direction such that first and second tractive elements are longitudinally offset from the first lateral axis and spaced from the first end of the base. The second assembly is pivotably coupled to the third and fourth pivot points. The second assembly extends away from the base in a second direction such that third and fourth tractive elements are longitudinally offset from the second lateral axis and spaced from the second end of the base.

The present invention relates to a safety protection device, disclosing an anti-squeezing device for mobile console, comprising: an opening/closing mechanism pivotally mounted in the area of an operating desktop of the mobile console, capable of pivotally opening from a closed state in a direction away from the operator in response to the squeezing thrust of the operator to form a dodging space; and a position signal detection mechanism mounted to detect and transmit an opening/closing position signal of the opening/closing mechanism, so that a control unit of the mobile console may perform control operations based on the opening/closing position signal. The present invention further discloses an application-specific pusher-type anti-squeezing device for mobile console and an aerial work machine. The anti-squeezing device provided by the present invention can provide an effective dodging space while performing anti-squeezing operation, and has the advantages of wide protection angle range, high safety and high stability.

Disclosed embodiments include pan assemblies for aerial work platforms, methods of attaching a pan assembly to an aerial work platform, and methods of fabricating a pan assembly for an aerial work platform. In an illustrative embodiment given by way of non-limiting example, a non-limiting, illustrative pan assembly for an aerial work platform includes a pan configured to be disposed about a lower portion of a basket of an aerial work platform. A plurality of attachment mechanisms are disposed about an exterior of the pan, the plurality of attachment mechanisms being configured to removably attach the pan to a lower portion of a basket of an aerial work platform. A tensioning system is disposed within an interior of the pan, the tensioning system being configured to cooperate with the plurality of attachment mechanisms to hold the pan onto a lower portion of a basket of an aerial work platform.

Systems and methods for detecting attachment of a lanyard at a utility platform of an aerial device are described. In some embodiments, a lanyard attachment device is disposed on a utility platform. The lanyard attachment device may comprise a sensor detecting when a lanyard is attached to the lanyard attachment device. In some embodiments, the utility platform is separated from a base of the aerial device by a dielectric gap, and a light signal is indicative of the state of the lanyard attachment device. Furthermore, anti-tie-down functionality may be used to detect error or tampering of the lanyard attachment device.

A tilting support or work bucket, or apparatus for an aerial lift including a support frame for supporting an operator. The support frame can have a seat for supporting the operator when in an upright position and a chest support having a portion above and forward of the seat for supporting a chest of the operator when in a forwardly downward tilted position while allowing arms of the operator to extend forwardly out of the support frame. A support member can be pivotably mounted to the support frame at a pivot joint that is located at an upper portion of the support frame when the support frame is in the upright position, for pivotably supporting the support frame. An actuator can be included for positionably rotating the support frame relative to the support member about the pivot joint between the upright position and the forwardly downward tilted position. Since the pivot joint is located in the upper portion of the support frame, pivoting of the support frame from the upright position to the forwardly downward tilted position moves a center of gravity of the support frame rearwardly in the direction of the support member.