A storage insert for inserting in a storage device, having a storage body with an upper side for receiving storage goods, a lower side with receiving structures in a receiving region for receiving a sensor rail, and at least one optically transparent section between the receiving region and the upper side, and having the sensor rail, which is configured to be received in the receiving region by the receiving structures, and which has at least one sensor element in the region of the at least one optically transparent section is illustrated and described. The storage body is formed as a punched and bent storage sheet.

Provided are systems, methods, and devices for storing and transporting articles with a multi-shelf storage unit. A system for article handling includes a multi-shelf storage unit and a robotic unit. The multi-shelf storage unit includes a plurality of shelves disposed on a frame, the plurality of shelves including at least one vertically moveable shelf configured to move in first and second vertical directions relative to the frame, and a lift mechanism configured to automatically drive, in response to receiving a drive input, the at least one vertically moveable shelf in the first or second vertical direction. The robotic unit includes an end effector disposed on a robotic manipulator for engaging an article and a lift mechanism actuator that is connectable to the lift mechanism and configured to provide the drive input to actuate the lift mechanism.

A trolley assembly for overhead track testing is provided. In one example embodiment, a trolley assembly includes an idle roller that rotates about a first axis, a first top roller coupled to a first end of the idle roller via a first trolley upright support, and a second top roller coupled to a second end of the idle roller via a second trolley upright support. The trolley assembly includes a cantilever coupled to the idle roller. The trolley assembly includes a driveshaft coupled to a first end of the cantilever. The trolley assembly includes at least one motor coupled to the drive shaft.

A support element for storing crates, wherein the support element is an elongate element having a cross section that is substantially formed in an U-shape, comprising a bottom section and two opposite side walls extending from the bottom section. The side walls each comprise a top portion, forming two elongate supporting areas, whereby the elongate supporting areas are configured to support a crate or a column of stacked crates, The inner side sections of the side walls each comprise a step symmetrically protruding to the inside of the U-shape forming two elongate running surfaces, whereby the elongate running surfaces are configured to support a conveyor system for transporting the crate. The invention further refers to a support system, a storage system and to a rearing unit.

A storage and handling system for elongated tubing and bar stocks comprises a storage rack having cantilever arms. A material storage pallet is supported by the cantilever arms. The pallet is formed by a single-layer tubular frame having a pair of inset fork tubes to receive the tines of a forklift and which directly support loads carried on the pallet. A plurality of vertically-oriented receiving holes are disposed in transversely-aligned rows across the length of the pallet to receive a plurality of organizer pins that restrain therebetween elongated raw materials stacked transversely on the pallet. The system may be paired with a roller cart configured to transfer one of the pallets to and from the storage rack.

A pallet displacement system for a pallet storage assembly, including a pair of spaced apart rail assemblies, each rail assembly including a rail having plurality of rollers rotatably mounted thereon for supporting one or more pallet, a pallet engagement element slidingly engaged to the rail and a pair of springs operatively connecting the pallet engagement element to a front end of the rail on respective sides thereof. In use, the sequential positioning of a plurality of pallets onto the rail assemblies results in a first pallet engaging the pallet engagement elements, extending the springs and therefore accumulate potential energy. When one or more of the plurality of pallets is removed from the rail assemblies, the potential energy is transformed into kinetic energy, pulling the pallet engagement elements toward the front of the rail assemblies, which in turn displaces remaining pallets toward the front.

A mounting device (10) for connecting two support beams (20, 30, 40) of a rack has an attachment plate (11). The attachment plate (11) has a through-hole (14) arrangeable adjacent an opening (21) of a first (20) of the two support beams and at least one first engaging element (12) for engaging with a recess (31, 32) of a second (30; 40) of the two support beams when the attachment plate (11) is arranged with a first flat side (11C) facing the first support beam (20). The mounting device (10) further has an eccentric stud (15) insertable into the through-hole (14) of the attachment plate (11) and the opening (21) of the first support beam (20). Therein, turning the eccentric stud (15) adjusts a position of the first engaging element (12) in the recess (31, 32) of the second support beam (30; 40).

A method for constructing a carton flow bed rack (1) includes specifying a number of levels of the carton flow bed rack (1). The method also includes specifying whether and where each level has a load end, and/or an unload end, and/or a stop end. The method further includes specifying at least one of a height, a width, and a depth of the carton flow bed rack and providing and dimensioning components for assembling the carton flow bed rack according to the specifications.

The invention proposes a dynamic storage rack unit for providing material in logistics and/or manufacturing processes, having a plurality of storage rack compartments (3) inclined in the longitudinal direction, each storage rack compartment (3) being designed to accommodate a plurality of material containers (4) arranged beside one another in the longitudinal direction, storage rack compartments (3) each having a plurality of sensors (5) for monitoring the filling level of the respective storage rack compartment (3), a distance (A) which corresponds substantially to the length of the material containers (4) to be accommodated in the storage rack compartment (3) being provided in the longitudinal direction between sensors (5) of the respective storage rack compartment (3), storage rack compartments (3) each having at least one state display apparatus (10) for displaying the state and/or filling level of the respective storage rack compartment (3), which unit at least partially improves the disadvantages of the prior art. According to the invention, this is achieved by virtue of the fact that storage rack compartments (3) each comprise at least one compartment checking unit (6) for checking the respective sensors (5) of the respective storage rack compartment (3), the compartment checking units (6) each being in the form of energy and data transmission units (6) for supplying the respective sensors (5) of the respective storage rack compartment (3) with electrical energy and for acquiring, receiving and transmitting sensor data from the respective sensors (5) of the respective storage rack compartment (3), at least one storage rack checking unit (7) for checking a plurality of compartment checking units (6) of the storage rack compartments (3) being provided, the at least one storage rack checking unit (7) being designed to supply the plurality of compartment checking units (6) of the respective storage rack compartments (3) with electrical energy and to acquire, receive and transmit data from the plurality of compartment checking units (6) of the respective storage rack compartments (3), at least one central checking unit (11, 12, 13) for checking the at least one storage rack checking unit (7) being provided, the central checking unit (11, 12, 13) being designed to acquire, receive and transmit data from the at least one storage rack checking unit (7).

A modular system for material storage and conveying having a layered storage section with two or more storage layers having conveyors, the layered storage section being associated with a load section and a delivery section having their own conveyors at each end of the layered storage section, and elevators that can selectively position the load and delivery section at operational heights of the conveyors of the layered storage section.