Conventionally, loading and unloading pallets occurred in a factory like environment, wherein traditional systems were used for stacking pallets vertically for retrieval thereof. However, these pallets arrive from a roller conveyer and such set-ups are purely based on the concept of storage purpose and lack in palletizing and depalletizing in effective manner. Embodiments of the present disclosure provide pallet loading and unloading apparatus for automated objects manipulation, wherein pallet(s) from a forklift jack arrives on a linear slider assembly for movement of pallet from loading area to manipulating area using two double-sided cylinders associated thereof. Rollers comprised in apparatus provide flexibility to linear slider to slide freely on top. Manipulator performs palletizing and depalletizing as applicable. During depalletizing, empty pallet is slide down using actuator(s) and guided pins and pushed back to bottom rollers which is below a L-channel and is pushed out towards bottom ramp at pallet exit area.

Conventionally, loading and unloading pallets occurred in a factory like environment, wherein traditional systems were used for stacking pallets vertically for retrieval thereof. However, these pallets arrive from a roller conveyer and such set-ups are purely based on the concept of storage purpose and lack in palletizing and depalletizing in effective manner. Embodiments of the present disclosure provide pallet loading and unloading apparatus for automated objects manipulation, wherein pallet(s) from a forklift jack arrives on a linear slider assembly for movement of pallet from loading area to manipulating area using two double-sided cylinders associated thereof. Rollers comprised in apparatus provide flexibility to linear slider to slide freely on top. Manipulator performs palletizing and depalletizing as applicable. During depalletizing, empty pallet is slide down using actuator(s) and guided pins and pushed back to bottom rollers which is below a L-channel and is pushed out towards bottom ramp at pallet exit area.

The invention relates to a method for operating a palletizing plant (5) which comprises a palletizing apparatus (10) for forming a layer stack (100) and at least one driverless transport vehicle (40) for transporting the layer stack (100). In the method, the driverless transport vehicle (40) is moved to a palletizing location (41) close to the palletizing apparatus (10) and a layer stack (100) is formed on the driverless transport vehicle (40). The driverless transport vehicle (40) remains at the palletizing location (41) during the formation of the layer stack (100). The invention also relates to a palletizing plant (5) which is set up to carry out the method according to the invention.

The invention relates to a method for operating a palletizing plant (5) which comprises a palletizing apparatus (10) for forming a layer stack (100) and at least one driverless transport vehicle (40) for transporting the layer stack (100). In the method, the driverless transport vehicle (40) is moved to a palletizing location (41) close to the palletizing apparatus (10) and a layer stack (100) is formed on the driverless transport vehicle (40). The driverless transport vehicle (40) remains at the palletizing location (41) during the formation of the layer stack (100). The invention also relates to a palletizing plant (5) which is set up to carry out the method according to the invention.

A method for determining material-cage stacking, a computer device, and a storage medium are provided. The method includes the following. A material-cage image is obtained by photographing a first stacking apparatus of a first material cage and a second stacking apparatus of a second material cage. The stacking apparatuses of the two material cages in the material-cage image can be recognized respectively with two detection models. The first stacking result is obtained by obtaining location information of the stacking apparatuses of the two material cages with the first detection model, and the second stacking result is obtained with the second detection model.

A method for determining material-cage stacking, a computer device, and a storage medium are provided. The method includes the following. A material-cage image is obtained by photographing a first stacking apparatus of a first material cage and a second stacking apparatus of a second material cage. The stacking apparatuses of the two material cages in the material-cage image can be recognized respectively with two detection models. The first stacking result is obtained by obtaining location information of the stacking apparatuses of the two material cages with the first detection model, and the second stacking result is obtained with the second detection model.

In a clamping device, the number of components for an article detection means is reduced. In a stacker, a tire is placed on the carry surface. The first gripping member and the second gripping member grip a side of tire placed on the carry surface and include an abutment surface having a bent portion and are capable of abutting with the side of tire. The first sensor and the second sensor include a light axis in a direction along the article. The controller moves the first gripping member and the second gripping member close to each other to the first position where the tire is not gripped. When the tire is detected with the first sensor and second sensor, the controller moves the first gripping member and the second gripping member close to each other to the second position where the tire is gripped.

A material handling system, for handling and placing packages onto pallets destined for an order store, including a storage array, an automated package transport system, an automated palletizer, and a controller operably connected to the automated palletizer, the controller being programmed with a pallet load generator with at least one pallet to order store affinity characteristic, for a predetermined method of pallet load packages distribution at the order store, the pallet load generator being configured so that a pallet load is formed by the automated palletizer of packages arranged in the pallet load embodying the at least one pallet to order store affinity characteristic.

A material handling system, for handling and placing packages onto pallets destined for an order store, including a storage array, an automated package transport system, an automated palletizer, and a controller operably connected to the automated palletizer, the controller being programmed with a pallet load generator with at least one pallet to order store affinity characteristic, for a predetermined method of pallet load packages distribution at the order store, the pallet load generator being configured so that a pallet load is formed by the automated palletizer of packages arranged in the pallet load embodying the at least one pallet to order store affinity characteristic.

Object manipulation space optimization is a challenging task and used in applications such as heat treatment operation and transport packaging. Traditionally manual intervention is involved to grasp and place the objects for ensuring multi object stacking with zero gap between adjacent objects. This leads to higher cost infrastructure and low productivity. Further, conventional gripper devices fail to optimize object manipulation space and are unable to handle objects of different cross sections with larger lengths. The present disclosure provides a gripper apparatus addressing a single gripper design comprising an adaptor holding unit with a provision for different modular object holding units which are varied in accordance with size, shape and length of the object to be grasped and placed by the gripper apparatus. The modular object holding unit comprises a plurality of fingers which are actuated for grasping and stacking one or more objects such that object manipulation space is optimized.