A helically wound tubular structure formed from helically wound sheet metals is disclosed. The tubular structure has a first sheet metal helically wound about a longitudinal axis. A second sheet metal having voids disposed therein is helically wound about the longitudinal axis and coaxially about the first sheet metal. A third sheet metal is helically wound about the longitudinal axis and coaxially about the first sheet metal and the second sheet metal.

A helically wound tubular structure formed from helically wound sheet metals is disclosed. The tubular structure has a first sheet metal helically wound about a longitudinal axis. A second sheet metal having voids disposed therein is helically wound about the longitudinal axis and coaxially about the first sheet metal. A third sheet metal is helically wound about the longitudinal axis and coaxially about the first sheet metal and the second sheet metal.

Bending mandrils and related bending machines and methods are disclosed, which include at least one ultra-high molecular weight (UHMW) material. The mandril, which may comprise or consist of the UHMW material, is placed within an interior of a structure to be bent before the structure is bent about a bending die of the bending machine. Kerf cuts may be provided at the mandril for added flexibility. Other components of the bending machine, such as the following block and/or the bending die may also include panels of surfaces comprising a same or different UHMW material.

Bending mandrils and related bending machines and methods are disclosed, which include at least one ultra-high molecular weight (UHMW) material. The mandril, which may comprise or consist of the UHMW material, is placed within an interior of a structure to be bent before the structure is bent about a bending die of the bending machine. Kerf cuts may be provided at the mandril for added flexibility. Other components of the bending machine, such as the following block and/or the bending die may also include panels of surfaces comprising a same or different UHMW material.

Bending mandrils and related bending machines and methods are disclosed, which include at least one ultra-high molecular weight (UHMW) material. The mandril, which may comprise or consist of the UHMW material, is placed within an interior of a structure to be bent before the structure is bent about a bending die of the bending machine. Kerf cuts may be provided at the mandril for added flexibility. Other components of the bending machine, such as the following block and/or the bending die may also include panels of surfaces comprising a same or different UHMW material.

Bending mandrils and related bending machines and methods are disclosed, which include at least one ultra-high molecular weight (UHMW) material. The mandril, which may comprise or consist of the UHMW material, is placed within an interior of a structure to be bent before the structure is bent about a bending die of the bending machine. Kerf cuts may be provided at the mandril for added flexibility. Other components of the bending machine, such as the following block and/or the bending die may also include panels of surfaces comprising a same or different UHMW material.

Benders are disclosed relating to the convenient, accurate, and precise bending of tubing. Example benders include features such as a mandrel, adjustable mechanical stops, and scales having relatively high resolution along with significant distance from a central axis of the mandrel. Certain benders may include separate fine and coarse adjustments to bend angles and support mechanisms for controlling the bend plane angle.

Benders are disclosed relating to the convenient, accurate, and precise bending of tubing. Example benders include features such as a mandrel, adjustable mechanical stops, and scales having relatively high resolution along with significant distance from a central axis of the mandrel. Certain benders may include separate fine and coarse adjustments to bend angles and support mechanisms for controlling the bend plane angle.