A system and method for rigging and lifting a joined, multi-section assembly of corrugated decking sections for attachment to a Cold-Form Steel. The system and method provide for the utilization of an adaptable rig that securely attaches to a multi-section assembly of corrugated decking sections which have be pre-joined by workers in a safe, preferably terrestrial, workspace. The adaptability of the rig enables it to provide attachment points for lifting and supporting the multi-sectioned decking assemblies of disparate sizes and materials. The location and number of these attachment points being a function of the size, gauge, area and aggregate weight of a given pre-joined multi-section assembly. The system and method are can be utilized with pre-joined multi-section assemblies consisting of individual decking sections fabricated from a variety of materials, including ferrous metals, non-ferrous metals, as well as composite materials.

Present embodiments relate to an apparatus and method which separates tie plates. More specifically, and without limitation, present embodiments relate to a tie plate separator which can retrieve tie plates from a pile and separates such for placement on a feeder, such as a conveyor for sequential feeding of the tie plates.

Present embodiments relate to an apparatus and method which separates tie plates. More specifically, and without limitation, present embodiments relate to a tie plate separator which can retrieve tie plates from a pile and separates such for placement on a feeder, such as a conveyor for sequential feeding of the tie plates.

A work machine includes a lower traveling structure, an upper swing structure mounted on the lower traveling structure via a swing mechanism, an attachment attached to the upper swing structure, a lifting magnet attached to the attachment, a hardware processor configured to calculate the weight of an object lifted by the lifting magnet, and a display device configured to display the weight of the object calculated by the hardware processor.

A work machine includes a lower traveling structure, an upper swing structure mounted on the lower traveling structure via a swing mechanism, an attachment attached to the upper swing structure, a lifting magnet attached to the attachment, a hardware processor configured to calculate the weight of an object lifted by the lifting magnet, and a display device configured to display the weight of the object calculated by the hardware processor.

An electromagnetic lifter for moving hot materials includes a ferromagnetic yoke formed by a horizontal core and two vertical polarities, coils wound around the core and enclosed in a container, a non-magnetic baffle arranged between the vertical polarities and below the container at a distance of at least 40 mm to protect the container from heat radiated by the hot material. The electromagnetic lifter also includes a first space between the container and the plurality of vertical polarities that maintains a first predetermined distance between the container and the plurality of vertical polarities, a second space between the container and the core that maintains a second predetermined distance between the container and the core, and a third space between the container and the non-magnetic baffle that allows a convective flow of air. The electromagnetic lifter also includes side spacers disposed in the first space and top spacers disposed in the second space.

An electromagnetic lifter for moving hot materials includes a ferromagnetic yoke formed by a horizontal core and two vertical polarities, coils wound around the core and enclosed in a container, a non-magnetic baffle arranged between the vertical polarities and below the container at a distance of at least 40 mm to protect the container from heat radiated by the hot material. The electromagnetic lifter also includes a first space between the container and the plurality of vertical polarities that maintains a first predetermined distance between the container and the plurality of vertical polarities, a second space between the container and the core that maintains a second predetermined distance between the container and the core, and a third space between the container and the non-magnetic baffle that allows a convective flow of air. The electromagnetic lifter also includes side spacers disposed in the first space and top spacers disposed in the second space.

A lifter with electro-permanent magnets is provided. It has an external bearing structure closed at the bottom by a plate, provided with a heat shield, and pole pieces secured under the respective poles and protruding from the bottom plate. Each of the electro-permanent magnets has a reversible magnet arranged on top of one of the poles, of a fixed polarization magnet formed by a plurality of blocks placed along the lateral faces of the pole and of a coil arranged around the reversible magnet to cause the reversal of the polarization of the latter by means of an electrical pulse. An airtight air gap between 1 and 4 mm high is formed between each pole piece and the respective pole through the interposition of a plate of thermal insulation material that resists high temperatures provided at each pole with a rectangular window slightly smaller in size than the pole itself, with the top sides of the pole pieces and/or the bottom sides of the poles being provided with peripheral recesses suitable to act as seats for the positioning of the plate.

A lifter with electro-permanent magnets is provided. It has an external bearing structure closed at the bottom by a plate, provided with a heat shield, and pole pieces secured under the respective poles and protruding from the bottom plate. Each of the electro-permanent magnets has a reversible magnet arranged on top of one of the poles, of a fixed polarization magnet formed by a plurality of blocks placed along the lateral faces of the pole and of a coil arranged around the reversible magnet to cause the reversal of the polarization of the latter by means of an electrical pulse. An airtight air gap between 1 and 4 mm high is formed between each pole piece and the respective pole through the interposition of a plate of thermal insulation material that resists high temperatures provided at each pole with a rectangular window slightly smaller in size than the pole itself, with the top sides of the pole pieces and/or the bottom sides of the poles being provided with peripheral recesses suitable to act as seats for the positioning of the plate.

An electromagnetic pallet assembly includes electromagnetic cells coupled to a pallet base, and an electromagnetic pallet frame supported above the pallet base by pillars. A pallet central processing system is configured to control the electromagnetic cells and/or the pallet frame, and can be further configured to control an electromagnetic frame sheet located above the pallet frame. A signal adapter is configured to transmit signal between the central processing system and a remote control device. A method for adjusting pallet position includes selecting electromagnetic pallets, and activating an electromagnetic assembly of a truck bed surface and/or electromagnetic cells of the selected pallets. Polarity and/or strength of the electromagnetic assembly and/or the electromagnetic cells of the selected pallets are adjusted, and the selected pallets are moved.