A climbing system includes a treestand and a plurality of climbing sticks. The treestand includes a monolithic platform formed from strengthened material. Each of the climbing sticks includes a frame having a plurality of weight-reduction apertures formed therethrough. Methods of manufacturing a treestand and climbing sticks are also disclosed. The method of manufacturing a treestand includes providing a solid, strengthened piece of material and removing portions of the material to form openings between structural supports. The method of manufacturing a climbing stick includes providing a frame and forming a plurality of weight-reduction apertures therethrough.

A climbing system includes a treestand and a plurality of climbing sticks. The treestand includes a monolithic platform formed from strengthened material. Each of the climbing sticks includes a frame having a plurality of weight-reduction apertures formed therethrough. Methods of manufacturing a treestand and climbing sticks are also disclosed. The method of manufacturing a treestand includes providing a solid, strengthened piece of material and removing portions of the material to form openings between structural supports. The method of manufacturing a climbing stick includes providing a frame and forming a plurality of weight-reduction apertures therethrough.

A jig for machining portions a firearm lower receiver blank. The jig can include a side plate assembled with a top plate. The top plate can include an access aperture for machining the fire control group aperture within the blank. The side plate can include drill apertures for drilling out trigger, hammer, and selector holes. The jig can include an adjustable alignment mechanism for aligning a top surface of the blank with the top plate. The jig can include a hand drill stabilizer for attachment with the side plates.

A jig for machining portions a firearm lower receiver blank. The jig can include a side plate assembled with a top plate. The top plate can include an access aperture for machining the fire control group aperture within the blank. The side plate can include drill apertures for drilling out trigger, hammer, and selector holes. The jig can include an adjustable alignment mechanism for aligning a top surface of the blank with the top plate. The jig can include a hand drill stabilizer for attachment with the side plates.

An aluminum foil rolling process includes: providing first and second aluminum foils, each having first and second faces; lubricating one face between the first and second faces to obtain a first lubricated face; coupling the first and second foils, thereby obtaining a coupled foil having two outer faces; rolling the coupled foil, reducing the thickness of the coupled foil; lubricating one face between the two outer faces of the coupled foil, obtaining a coupled foil having a second lubricated face; winding the coupled foil having the second lubricated face, obtaining a wound coupled foil; partially separating the coupled foil by unwinding one of the first and second foils, obtaining a wound coupled foil; unwinding the wound coupled foil; rolling the coupled foil thereby obtaining a coupled foil with reduced thickness; separating the coupled foil with reduced thickness obtaining a first and second foils with respective first and second reduced thicknesses.

A photovoltaic module mounting system may include a module clamp that includes a central section that includes two first walls connected at the top of each first wall by a first connecting surface. The central section may have a first cross-sectional height corresponding to a height of each of the first walls and a first width corresponding to a distance between the two first walls. The module clamp may have ends that include two second walls connected at the top of each second wall by a second connecting surface in which each of the ends has a second cross-sectional height that is shorter than the first cross-sectional height and a second width that is wider than the first width. The central section may be connected to each of the ends such that the first connecting surface and the second connecting surface are bridged and form a bowtie shape.

A photovoltaic module mounting system may include a module clamp that includes a central section that includes two first walls connected at the top of each first wall by a first connecting surface. The central section may have a first cross-sectional height corresponding to a height of each of the first walls and a first width corresponding to a distance between the two first walls. The module clamp may have ends that include two second walls connected at the top of each second wall by a second connecting surface in which each of the ends has a second cross-sectional height that is shorter than the first cross-sectional height and a second width that is wider than the first width. The central section may be connected to each of the ends such that the first connecting surface and the second connecting surface are bridged and form a bowtie shape.

An excisional device for either handheld or stereotactic table use may comprise an outer sheath that may comprise a distal trough shape configured to penetrate and/or cut tissue independently or in concert with work element(s). The articulable work element(s) may comprise articulable beak(s) and may be configured to translate and/or rotate at a first rate and to cut tissue in a direction implied by placement of the trough shaped outer sheath. A first helical element or equivalent assembly may be configured to transport tissue cut by the work element(s) and/or trough, may be co-axially disposed relative to the work element(s) and may be operative to rotate at a second rotation rate that is different than the first rate. A proximal sheath may be co-axially disposed relative to the work element(s) and the first helical element, and may be configured to rotate and actuate the work element(s).

An excisional device for either handheld or stereotactic table use may comprise an outer sheath that may comprise a distal trough shape configured to penetrate and/or cut tissue independently or in concert with work element(s). The articulable work element(s) may comprise articulable beak(s) and may be configured to translate and/or rotate at a first rate and to cut tissue in a direction implied by placement of the trough shaped outer sheath. A first helical element or equivalent assembly may be configured to transport tissue cut by the work element(s) and/or trough, may be co-axially disposed relative to the work element(s) and may be operative to rotate at a second rotation rate that is different than the first rate. A proximal sheath may be co-axially disposed relative to the work element(s) and the first helical element, and may be configured to rotate and actuate the work element(s).

A mold block includes a tool body with a contoured finished surface adapted to receive a tool insert having a forming surface for forming a bottle neck in a molding operation. The tool body defines an internal channel for heat transfer with the forming surface. At least a portion of the channel is offset generally equidistant from the finished surface to provide a path contoured for conformal cooling of the insert. The tool body has a pair of ports intersecting the channel. Several methods for forming a mold block are disclosed and include machining a contoured finished surface adapted to receive a tool insert on a tool body, forming a heat transfer channel within the tool body, and forming a pair of ports into the tool body. At least a portion of the channel is offset generally equidistant from the finished surface for conformal cooling of the insert.