Provided is a cable retention device to facet attachments and projections onto an enclosure. The device includes an inner and outer planar layer which include an inner and outer cutout respectively. The inner and outer planar layers are attached and aligned so the inner and outer cutouts overlap. The inner planar layer includes a pair of vertical slotted cutouts connected by a center cutout to form a plurality of pinch points. Each vertical slotted cutout includes an inner edge and an outer edge.

Provided is a cable retention device to facet attachments and projections onto an enclosure. The device includes an inner and outer planar layer which include an inner and outer cutout respectively. The inner and outer planar layers are attached and aligned so the inner and outer cutouts overlap. The inner planar layer includes a pair of vertical slotted cutouts connected by a center cutout to form a plurality of pinch points. Each vertical slotted cutout includes an inner edge and an outer edge.

Provided is a cable retention device to facet attachments and projections onto an enclosure. The device includes an inner and outer planar layer which include an inner and outer cutout respectively. The inner and outer planar layers are attached and aligned so the inner and outer cutouts overlap. The inner planar layer includes a pair of vertical slotted cutouts connected by a center cutout to form a plurality of pinch points. Each vertical slotted cutout includes an inner edge and an outer edge.

Provided is a cable retention device to facet attachments and projections onto an enclosure. The device includes an inner and outer planar layer which include an inner and outer cutout respectively. The inner and outer planar layers are attached and aligned so the inner and outer cutouts overlap. The inner planar layer includes a pair of vertical slotted cutouts connected by a center cutout to form a plurality of pinch points. Each vertical slotted cutout includes an inner edge and an outer edge.

Provided is a cable retention device to facet attachments and projections onto an enclosure. The device includes an inner and outer planar layer which include an inner and outer cutout respectively. The inner and outer planar layers are attached and aligned so the inner and outer cutouts overlap. The inner planar layer includes a pair of vertical slotted cutouts connected by a center cutout to form a plurality of pinch points. Each vertical slotted cutout includes an inner edge and an outer edge.

A mount system and method of manufacture for e.g. a machine vision camera is disclosed. The mount system comprises a rectangular base, a lower clamp disc, an upper clamp disc, a tilting plate, an expansion clamp, and an O-ring. The expansion clamp comprises a tapered head screw and an expandable mandrel, both typically made of stainless steel. The mount system facilitates improved machine vision by enabling effective mounting of machine vision cameras in smaller spaces and/or spaces requiring unusual angles and intricate positioning. The mount system is also advantageous in inhospitable environments having harsh environmental factors. The mount system is also easier for machine vision personnel to learn and understand.

A mount system and method of manufacture for e.g. a machine vision camera is disclosed. The mount system comprises a rectangular base, a lower clamp disc, an upper clamp disc, a tilting plate, an expansion clamp, and an O-ring. The expansion clamp comprises a tapered head screw and an expandable mandrel, both typically made of stainless steel. The mount system facilitates improved machine vision by enabling effective mounting of machine vision cameras in smaller spaces and/or spaces requiring unusual angles and intricate positioning. The mount system is also advantageous in inhospitable environments having harsh environmental factors. The mount system is also easier for machine vision personnel to learn and understand.

A constructing-and-forging method for preparing homogenized forged pieces comprises: preparing preformed billets: cutting off a plurality of continuous casting billets, milling and smoothing surfaces of the billets to be welded, performing vacuum plasma cleaning operation to the surfaces to be welded, stacking the plurality of billets and sealing around the surfaces in a vacuum chamber by electron beam welding; forge-welding and homogenizing the preformed billets: heating the preformed billets to a certain temperature in a heating furnace and taking the heated preformed billets out of the heating furnace, forging the preformed billets by a hydraulic press, then using three-dimensional forging to disperse the welded surfaces such that composition, structure and inclusion of the interface areas are at the same level as those of the bodies of the billets. Cheap continuous casting billets are stacked and forge welded.

A punching device for punching a workpiece includes a punching part and a broaching part. The punching part has a punching cutting edge that limits a punching cutting area, the punching part being intended to pierce the workpiece. The broaching part is intended to tear the workpiece later than the punching part, and includes at least a broaching tooth with a cutting edge that limits a cutting area which is greater than the punching cutting area.

A machining tool assembly for manufacturing a firearm lower receiver includes a first and second side jig which are configured to be disposed on opposite sides of the firearm lower receiver and configured to removably attach to one another securing the firearm lower receiver therebetween. A drill block jig is removably attachable to the first and second side jigs disposed above the top surface of the firearm lower receiver, wherein the drill block jig has at least one through hole. A router support plate is disposed above and removably attachable to the first and second side jigs. A router aperture is disposed through a router support plate thickness.