A carrier for transporting goods includes a supporting mechanism, a lifting mechanism, a first detection component, and a controller. The supporting mechanism includes at least one entrance and connected to a mobile robot. The lifting mechanism includes a lifting driving member and a bearing part. The lifting driving member is arranged on the supporting mechanism, and the bearing part is arranged on the lifting driving member to be driven to be elevated or lowered by the lifting driving member. The first detection component is arranged on the bearing part and is located in front of the at least one entrance for detecting a position of the goods. The controller is arranged on the supporting mechanism and is respectively communicatively connected with the lifting driving member, the first detection component, and the mobile robot. A mobile lifting conveyor having the carrier is also provided.

A carrier for transporting goods includes a supporting mechanism, a lifting mechanism, a first detection component, and a controller. The supporting mechanism includes at least one entrance and connected to a mobile robot. The lifting mechanism includes a lifting driving member and a bearing part. The lifting driving member is arranged on the supporting mechanism, and the bearing part is arranged on the lifting driving member to be driven to be elevated or lowered by the lifting driving member. The first detection component is arranged on the bearing part and is located in front of the at least one entrance for detecting a position of the goods. The controller is arranged on the supporting mechanism and is respectively communicatively connected with the lifting driving member, the first detection component, and the mobile robot. A mobile lifting conveyor having the carrier is also provided.

A tiller head for an industrial truck is shown which comprises a central portion, a left handle portion that is attached to a left side of the central portion and a right handle portion that is attached to a right side of the central portion, which is opposite to its left side, and an actuating element. The handle portions and the central portion define a front side of the tiller head and a back side of the tiller head, which is opposite to its front side. The front side of the tiller head and the back side of the tiller head extend transverse to the left side of the central portion and the right side of the central portion. The actuating element has an operable front surface and an operable back surface, and the actuating element is mounted to a front side of the central portion.

A materials handling vehicle includes a camera, odometry module, processor, and drive mechanism. The camera captures images of an identifier for a racking system aisle and a rack leg portion in the aisle. The processor uses the identifier to generate information indicative of an initial rack leg position and rack leg spacing in the aisle, generate an initial vehicle position using the initial rack leg position, generate a vehicle odometry-based position using odometry data and the initial vehicle position, detect a subsequent rack leg using a captured image, correlate the detected subsequent rack leg with an expected vehicle position using rack leg spacing, generate an odometry error signal based on a difference between the positions, and update the vehicle odometry-based position using the odometry error signal and/or generated mast sway compensation to use for end of aisle protection and/or in/out of aisle localization.

A materials handling vehicle includes a camera, odometry module, processor, and drive mechanism. The camera captures images of an identifier for a racking system aisle and a rack leg portion in the aisle. The processor uses the identifier to generate information indicative of an initial rack leg position and rack leg spacing in the aisle, generate an initial vehicle position using the initial rack leg position, generate a vehicle odometry-based position using odometry data and the initial vehicle position, detect a subsequent rack leg using a captured image, correlate the detected subsequent rack leg with an expected vehicle position using rack leg spacing, generate an odometry error signal based on a difference between the positions, and update the vehicle odometry-based position using the odometry error signal and/or generated mast sway compensation to use for end of aisle protection and/or in/out of aisle localization.

There is huge demand for automation in manufacturing, logistics, postal, distribution centers, ecommerce, retail. Typical scissor lift designs can carry large payload but are larger in size. There is a need for a compact fork with more payload carrying capacity. The dual side actuated scissor fork type lift unit is provided. The dual side actuated scissor fork type lift unit includes a top plate, a bottom plate, one or more linear motion (LM) blocks mounted on one or more linear guides, one or more mounting blocks mounted on the one or more LM blocks, and slot on a first end of at least one actuation link is connected to the bottom plate through a pin. The one or more LM blocks is free to slide on the one or more linear guides. The one or more mounting blocks moves along with a motion of the one or more LM blocks.

There is huge demand for automation in manufacturing, logistics, postal, distribution centers, ecommerce, retail. Typical scissor lift designs can carry large payload but are larger in size. There is a need for a compact fork with more payload carrying capacity. The dual side actuated scissor fork type lift unit is provided. The dual side actuated scissor fork type lift unit includes a top plate, a bottom plate, one or more linear motion (LM) blocks mounted on one or more linear guides, one or more mounting blocks mounted on the one or more LM blocks, and slot on a first end of at least one actuation link is connected to the bottom plate through a pin. The one or more LM blocks is free to slide on the one or more linear guides. The one or more mounting blocks moves along with a motion of the one or more LM blocks.

A lifter device includes: a pole; a lifting member configured to be guided by the pole; a motor configured to generate power used for ascending and descending of the lifting member; a transmission mechanism configured to transmit the power of the motor to the lifting member; and a preventing member configured to prevent the descending of the lifting member when the power is not transmitted.

A control system for a lift truck comprises: human-control devices generating manual-guidance signals for actuators of the vehicle, said devices including a hydraulic steering system, a control module (1) including an automatic-control submodule generating autonomous-guidance signals intended for one or more actuators of the vehicle, depending on setpoint signals, a switching module (2) designed to select one or more manual guidance signals and/or one or more autonomous-guidance signals, and an electrohydraulic valve enabling the conversion of a guidance signal stemming from the automatic-control module into a signal intended for the hydraulic steering system The system includes, in addition, a servo controller of the electrohydraulic valve, comprising a proportional-integral controller, an on/off controller and means for activation of one or other of the PI and ON/OFF controllers, depending on a speed threshold of the lift truck.

A transport apparatus includes a body; a fork having one portion supported by the body and another portion protruded from the body; a lifting unit; a control unit; a primary rotatable member mounted at a front end portion of the fork; an auxiliary rotatable member mounted at a rotatable-member-attaching position of the fork closer to a front end portion or a rear end portion of the fork compared to the primary rotatable member; and a step detection unit, disposed at a detection-unit-attaching position of the fork closer to the front end portion or closer to the rear end portion of the fork compared to the auxiliary rotatable member, and the step detection unit configured to detect a step member of a carriage base. The control unit lowers the fork using the lifting unit in response to a detection of the step member by the step detection unit.