An apparatus 10 for removing the skin of poultry pieces at a skinning station 12 includes an infeed conveyor 14 for transporting or feeding poultry pieces to the skinning station 12. The infeed conveyor 14 includes an endless belt 16 that is trained around an end roller 18 at the downstream end of the infeed conveyor. A pinch block 20 is configured with a concave pinch surface 22 having curvature closely following the curvature of the endless belt 16 trained around the end roller 18 to define a narrow gap 24 therebetween for capturing the skin of the poultry piece and forcing the skin through the gap 24, thereby pulling the skin away from the underlying flesh of the poultry piece. A transfer roller 26 assists in transferring the skinned poultry piece to an outfeed conveyor 28. A hold down structure 30 is provided for applying downward pressure on the poultry piece as the poultry piece is carried by the infeed conveyor 14 towards the skinning station 12, while the poultry skin is being removed, and also while the skinned poultry piece is being transferred to the outfeed conveyor 28.

An apparatus 10 for removing the skin of poultry pieces at a skinning station 12 includes an infeed conveyor 14 for transporting or feeding poultry pieces to the skinning station 12. The infeed conveyor 14 includes an endless belt 16 that is trained around an end roller 18 at the downstream end of the infeed conveyor. A pinch block 20 is configured with a concave pinch surface 22 having curvature closely following the curvature of the endless belt 16 trained around the end roller 18 to define a narrow gap 24 therebetween for capturing the skin of the poultry piece and forcing the skin through the gap 24, thereby pulling the skin away from the underlying flesh of the poultry piece. A transfer roller 26 assists in transferring the skinned poultry piece to an outfeed conveyor 28. A hold down structure 30 is provided for applying downward pressure on the poultry piece as the poultry piece is carried by the infeed conveyor 14 towards the skinning station 12, while the poultry skin is being removed, and also while the skinned poultry piece is being transferred to the outfeed conveyor 28.

The present invention relates to a mining system including a continuous miner. The continuous miner mines material and includes a miner navigation system. The mining system further includes a flexible conveyor system for receiving the mined material from the continuous miner. The flexible conveyor system includes a conveyor navigation system. The mining system further includes control means for controlling the miner navigation system and the conveyor navigation system so that the flexible conveyor system receives the mined material from the continuous miner. Preferably, the flexible conveyor system need not be coupled to the continuous miner, and can be extracted separately in the event of a cave-in on the miner.

A middle guide is located between a first transporter and a second transporter in a width direction in an area of a conveyor device extending in a transportation direction including a joint connecting to a support conveying device to guide a bottom middle portion of a bottom surface, and the bottom middle portion is a portion of the bottom surface between a bottom first portion and a bottom second portion in the width direction. The middle guide has a middle guide surface to guide the bottom middle portion, and the middle guide surface is located in a reference plane at the joint and inclined further downward at a greater distance from the joint.

A storage apparatus for transport goods includes a first conveyor, a second conveyor and a deflecting mechanism for deflecting transport goods conveyed by the first conveyor onto the second conveyor. A motor configuration is provided for motorized driving of the first conveyor and/or the second conveyor. A step is provided over which the transport goods are conveyed. The storage apparatus is configured to vertically compress the transport goods with the aid of the step. A method for storing transport goods, in particular packages, is also provided.

A turnout for use with two transport sections includes a turnout arm rotatably supported with respect to a first axis of rotation, guided linearly movably in the direction of the first axis, and movable between two end positions. The turnout arm has a deflection surface configured such that, when the turnout arm is in a first end position, a transported item can be transferred between the first and second transport sections via the deflection surface, and the turnout arm is located beneath the transport level in a second end position such that the transported item is movable along the first transport section beyond the turnout. The turnout arm is connected for driving, via a transmission, to a single electric motor such that it is movable back and forth between the first and second end positions solely by being driven by the electric motor in two degrees of freedom.

An object processing system is disclosed that includes a plurality of track sections, and a plurality of remotely actuatable carriers for controlled movement along at least portions of the plurality of track sections, wherein each of the remotely controllable carriers is adapted to support and transport an object processing bin.

Automated systems and processes for manufacturing post-tension tendons are provided. In one embodiment the system may comprise a conveyor configured to introduce a pre-determined length of a tendon into a tub; a cutter configured to cut the tendon when it meets the pre-determined length; and (c) a control unit configured for a user to input the pre-determined length and a pre-determined bundle diameter. The control until is typically operably connected to the cutter and to the tub. Advantageously, the tub is configured to coil the tendon to form a tendon bundle and tie the tendon bundle in the predefined bundle diameter. A movable seater station may be employed to fasten an anchor to one end of the strand and said seater station may be configured to move among two or more tubs. A manipulator may be employed to move and hang coiled tendons.

Automated systems and processes for manufacturing post-tension tendons are provided. In one embodiment the system may comprise a conveyor configured to introduce a pre-determined length of a tendon into a tub; a cutter configured to cut the tendon when it meets the pre-determined length; and (c) a control unit configured for a user to input the pre-determined length and a pre-determined bundle diameter. The control until is typically operably connected to the cutter and to the tub. Advantageously, the tub is configured to coil the tendon to form a tendon bundle and tie the tendon bundle in the predefined bundle diameter. A movable seater station may be employed to fasten an anchor to one end of the strand and said seater station may be configured to move among two or more tubs. A manipulator may be employed to move and hang coiled tendons.

A smart moving platform for transport of components in manufacturing includes a vehicle body, a transmission device, a conveying system, a detection device, a tag installation device, a control unit, and a tag reader. The conveying system conveys components. The detection device detects a location of the component and in a first predetermined area, the tag installation device installs and activates a tag on the component. The control unit writes component information to the activated tag and sets a predetermined period. The tag starts to count time elapsing, and the conveyor belt conveys the component to a second predetermined area. The tag reader reads the component information, the elapsed time, and a predetermined period of the tag. When the elapsed time matches the predetermined period, the conveying system sends the component to a third predetermined area.