A plant for producing a structured cross-channel packing element. The structured cross-channel packing element comprises at least two adjacent layers made of expanded metal sheets each comprising periodic deformations. The plant comprises a stretching machine configured to cut and stretch a metal sheet to form one of a plurality of first expanded metal sheets, a calibration machine configured to roll the first expanded metal sheets to a desired thickness, a sheet storage unit configured to directly receive each of the first expanded metal sheets rolled in the calibration machine, a forming machine configured to form each of the first expanded metal sheets to form the expanded metal sheets comprising periodic deformations, and a stacking machine configured to stack the expanded metal sheets comprising periodic deformations to form the structured cross-channel packing element. The sheet storage unit is configured to release the first expanded metal sheets directly to the forming machine.

A snow guard for a standing seam metal roof, which may impede falling or melting snow and ice and may prevent gutters from being overwhelmed by falling or melting snow and ice. Such a snow guard may be fitted to the standing seams of the roof by screws or similar fasteners. The snow guard may prevent leakage through the holes created by the fasteners, may aesthetically blend into the material of the standing seam metal roof system, and may function as a base for scaffold systems. Such a snow guard may also add strength to the panels on which it is disposed. Finally, such a snow guard may also have the benefit of being easy to install.

A snow guard for a standing seam metal roof, which may impede falling or melting snow and ice and may prevent gutters from being overwhelmed by falling or melting snow and ice. Such a snow guard may be fitted to the standing seams of the roof by screws or similar fasteners. The snow guard may prevent leakage through the holes created by the fasteners, may aesthetically blend into the material of the standing seam metal roof system, and may function as a base for scaffold systems. Such a snow guard may also add strength to the panels on which it is disposed. Finally, such a snow guard may also have the benefit of being easy to install.

A method of manufacturing a fishing jig hook allows a user to create a custom fishing jig hook that attracts fish. A user can attract specific fish by using jigs that mimic the appearances of the smaller bait fish that the target fish usually consumes. The fishing jig produced is reusable, thus reducing waste due to extended periods of fishing. Further, the fishing jig is bent to provide a hydrodynamic shape. The formed apparatus provides a malleable disk, a fishing jig hook, a metal-cutting tool, a folding rod, a ruler, a marker, a metal-puncturing tool, and at least one ornament. These tools include the necessary jig lure material required as well as the tools needed to subsequently shape that material.

A method of manufacturing a fishing jig hook allows a user to create a custom fishing jig hook that attracts fish. A user can attract specific fish by using jigs that mimic the appearances of the smaller bait fish that the target fish usually consumes. The fishing jig produced is reusable, thus reducing waste due to extended periods of fishing. Further, the fishing jig is bent to provide a hydrodynamic shape. The formed apparatus provides a malleable disk, a fishing jig hook, a metal-cutting tool, a folding rod, a ruler, a marker, a metal-puncturing tool, and at least one ornament. These tools include the necessary jig lure material required as well as the tools needed to subsequently shape that material.

This invention provides process for manufacturing a galvanized metal three-dimensional object with a shape including multiple edges, said process comprising, in the following order, the steps of: (A) providing and cutting a metal sheet matrix with a thickness within a range from 0.8 mm to 6 mm, the shape of said metal sheet matrix including multiple free edges, (B) batch-wise hot dipping said metal sheet matrix into a molten zinc alloy galvanizing bath, (C) cold-forming the galvanized metal sheet matrix into a desired three-dimensional shape including multiple adjacent metal edges, and (D) cold-forming a series of joining points for fastening together said multiple adjacent metal edges, to form said galvanized metal three-dimensional object.

This invention provides process for manufacturing a galvanized metal three-dimensional object with a shape including multiple edges, said process comprising, in the following order, the steps of: (A) providing and cutting a metal sheet matrix with a thickness within a range from 0.8 mm to 6 mm, the shape of said metal sheet matrix including multiple free edges, (B) batch-wise hot dipping said metal sheet matrix into a molten zinc alloy galvanizing bath, (C) cold-forming the galvanized metal sheet matrix into a desired three-dimensional shape including multiple adjacent metal edges, and (D) cold-forming a series of joining points for fastening together said multiple adjacent metal edges, to form said galvanized metal three-dimensional object.

This application relates to a piece of cell processing equipment, a cell processing method, and a battery production line. The cell processing equipment includes: a first support assembly, configured to fix a cell body, where the first support assembly is able to rotate around a first rotation axis; a second support assembly, configured to fix the cell body, where the second support assembly is able to rotate around a second rotation axis, and the first rotation axis is disposed parallel to the second rotation axis; and a third support assembly, configured to fix a tab and an end cap. The third support assembly includes a support seat and a shaping piece. An electrode post positioning groove is formed on the support seat. The shaping piece is disposed movably relative to the support seat.

This application relates to a piece of cell processing equipment, a cell processing method, and a battery production line. The cell processing equipment includes: a first support assembly, configured to fix a cell body, where the first support assembly is able to rotate around a first rotation axis; a second support assembly, configured to fix the cell body, where the second support assembly is able to rotate around a second rotation axis, and the first rotation axis is disposed parallel to the second rotation axis; and a third support assembly, configured to fix a tab and an end cap. The third support assembly includes a support seat and a shaping piece. An electrode post positioning groove is formed on the support seat. The shaping piece is disposed movably relative to the support seat.

A method for forming a sill pan is provided that includes the measurement of a width and length of an opening sill to be sealed. A piece of flexible sill pan material is cut based on the measured opening sill. Fold lines and cuts are created in the piece to form the sill pan. The resulting sill pan is readily formed to have at least one attribute of self-adherence, draining without shims, nail hole self-sealing, and provision of dams without resort to frame cutting.