A product order fulfillment system including a multi-level transport system and a lifting transport system. Each level of the multi-level transport system having a corresponding independent asynchronous level transport system separate and distinct from the asynchronous level transport system corresponding to each other level of the multi-level transport system. Each independent lift axis of the lifting transport system being configured to independently hold at least one case and being communicably coupled to each asynchronous level transport system so as to provide for exchange of the at least one case between each asynchronous level transport system and each independent lift axis. Each independent lift axis is communicably coupled to each other independent lift axis of the more than one lift axis and forms a common output of mixed cases so as to create an ordered sequence of mixed cases in accordance to a predetermined case out ordered sequence.

A right angle transfer device has a conveying surface defined by a plurality of conveying members that are driven to convey objects in a conveyance direction. A diverting conveying member is mounted to a frame and is driven to divert objects in a direction angled away from the conveyance direction. A lift drive rotates a cam to move a bar in a substantially horizontal direction. The movement of the bar causes a frame link connected to the bar and the frame to raise and lower the frame. Once the frame has been moved upward to a sufficient extent, the diverting conveying member will be raised above the conveying members to come into contact with the object to thereby move and divert the object away from the conveyance direction.

A storage and order-picking system including a warehouse, wherein the warehouse includes a storage module formed by two racks including one rack aisle therebetween; separation stations associated with the storage module, each separation station having associated therewith a respective pick up location; separate conveying systems for feeding storage containers from the warehouse to the pick up locations of the separation stations, respectively; and a robot arranged between the separate conveyors such that the robot can pick up during one movement cycle from each of the separate conveying systems respectively one article and can deliver between the corresponding article pick up locations one article which has already been picked up to a deposition location.

A configurable assembly is provided for conveying products along a longitudinal direction; the assembly has a supporting structure and at least two conveyor units; at least one of said units is provided with at least two tracks which receive, in use, respective products and diverge from or converge towards each other along a lateral direction, proceeding longitudinally from an inlet to an outlet; the units are movable with respect to the supporting structure by the action of an actuator device between a working area and at least one storage area, so as to selectively arrange one of said units in the working area.

An automated warehouse unit includes two rows of fixed conveyors conveying the storage target object in a first direction, a receiving-side transfer unit provided on one end portion side of the two rows and extending in a second direction, and a shipping-side transfer unit provided on the other end portion side of the two rows and extending in the second direction. Each transfer unit includes a moving device configured to reciprocally move a moving body in the second direction between a position facing one fixed conveyor in the fixed conveyors and a position facing the other fixed conveyor in the fixed conveyors, and a transportation conveyor supported by the moving body and configured to transfer the storage target object to the two rows s in the first direction.

A material layered conveying device based on a disassembly line, including a front section conveyor belt, a rear section conveyor belt, and a lower conveyor belt. An interval between the front and rear section conveyor belts is provided with two sets of movable conveyor belts arranged in side by side parallel, a lifting conveyor belt is provided below the interval and adjacent to and horizontal with the lower conveyor belt, and a lifting conveyor belt elevator is provided under the lifting conveyor belt. The lifting conveyor belt is driven vertically up, and the lifting conveyor belt is horizontal with the front and rear section conveyor belts when the lifting conveyor belt is moved to a maximum distance. The device adopts the movable dual conveyor belts of the respective levels of the upper and lower conveyor belts, and can achieve synchronous high-low transferring of the material when the material is conveyed.

A method and system for automatically forming and handling compound pallet units including a pallet and a plurality of products stacked on the pallet. The method includes the steps of providing a conveyor device, at least one loading area provided for automatically receiving empty pallets and temporarily hosting compound pallet units to be transferred to a main conveyor, and at least one manipulator robot configured for picking selected products and placing the products on a pallet stationing at said loading station.

A lifting and lowering transportation device is capable of transporting articles between different delivery positions using transportation units, each including a lifting and lowering platform, a linear motor, and a chain. The lifting and lowering platform can pass through the delivery positions by moving along the circumferential track that is common to the transportation units. The linear motor generates the driving force to move the lifting and lowering platform along the circumferential track. The chain is loop-shaped and can circulate along the circulation track corresponding to the circumference path, and the linear motor moves the lifting and lowering platform by circulating the chain by the driving force generated by the linear motor. The circulation of the chain in each transportation unit is controlled independently of the other transportation units.

An automatic tray loading system and a use method of the same are provided, which includes a stacked tray assembly, including at least one tray which is stacked up, where the at least one tray is provided with several locating slots; a tray lifting platform which includes a tray supporting table being connected with a elevating mechanism; a tray pick and place platform having a working region covers a tray input module, where the tray pick and place platform includes a manipulator which is connected with a multidimensional motion mechanism; and a delivery table including a tray placement plate, where each of the tray placement plate is provided with a groove which is configured to place the at least one layer of trays, and each of the tray placement plates is connected with a linear driving mechanism.

A goods to operator workstation is attachable to an input and a discharge conveyor system. The goods to operator workstation comprises a container staging platform that receives a product container from the input conveyor system and linearly moves the product container to an order pick position for an operator to pick articles from. A holding platform is pivotally movable between the order pick position and a discharge position to discharge a picked order container onto the discharge conveyor system after picking. Wherein when the holding platform moves back to the order pick position, the holding platform passes through the staging platform to transfer the order container from the staging platform to the holding platform so that the staging platform can retract and receive a new order container from the input conveyor system while the operator is picking.