An apparatus for twist tying wire around intersecting rebar bars. The apparatus is configured to receive and discharge precut wire segments, form and wrap the wire around the rebar, and twist the wire securely around the rebar. The user merely positions the tool at the rebar intersection, release a wire segment into the work end of the tool, and with a single fluid motion move a slide mechanism up to bend the wire segment around the rebar and twist it about itself to tie the rebar together.

An apparatus for twist tying wire around intersecting rebar bars. The apparatus is configured to receive and discharge precut wire segments, form and wrap the wire around the rebar, and twist the wire securely around the rebar. The user merely positions the tool at the rebar intersection, release a wire segment into the work end of the tool, and with a single fluid motion move a slide mechanism up to bend the wire segment around the rebar and twist it about itself to tie the rebar together.

Disclosed is a rebar automating robot for rebar tying on at least one rebar intersection. The rebar automating robot includes a control box 120 and a processing device 108. The control box 108 includes at least one intersection detection sensor 104 and at least one positioning sensor 106. The at least one intersection detection sensor 104 and the at least one positioning sensor 106 identifies a location of the at least one rebar intersection of a work area. The method include (a) navigating, the rebar automating robot to a first rebar intersection for tying the first rebar intersection, (b) tying, by a rebar tying tool, the first rebar intersection of the work area, and (c) navigating, the rebar automating robot, from the first rebar intersection to a second rebar intersection for performing rebar tying at the second rebar intersection of the work area.

Fence mesh including line wires, and stay wires extending laterally across and intersecting the line wires to form a mesh, wherein a first type of wire knot is formed by a knot wire around the line wire and stay wire at intersections of the stay wires with the line wires in a primary zone, and wherein a second type of wire knot is formed by a knot wire around the line wire and stay wire at intersections of the stay wires with the line wires in a secondary zone, characterised in that the first type of wire knot is different from the second type of wire knot; and a machine for the formation of such a mesh.

Fence mesh including line wires, and stay wires extending laterally across and intersecting the line wires to form a mesh, wherein a first type of wire knot is formed by a knot wire around the line wire and stay wire at intersections of the stay wires with the line wires in a primary zone, and wherein a second type of wire knot is formed by a knot wire around the line wire and stay wire at intersections of the stay wires with the line wires in a secondary zone, characterised in that the first type of wire knot is different from the second type of wire knot; and a machine for the formation of such a mesh.

A net and method for creating the same, the net comprising: cables in two or more directions, wherein the cables in each of the directions are made of at least a first construct or a second construct, wherein each cable of a first construct in the first direction has neighboring cables in the first direction made of the second construct, and each cable of the first construct in the second direction has neighboring cables in the second direction made of the second construct.

A net and method for creating the same, the net comprising: cables in two or more directions, wherein the cables in each of the directions are made of at least a first construct or a second construct, wherein each cable of a first construct in the first direction has neighboring cables in the first direction made of the second construct, and each cable of the first construct in the second direction has neighboring cables in the second direction made of the second construct.

A method of manufacturing a tower structure includes printing and depositing, via a printhead assembly of an additive printing system, one or more printed layers of a wall of the tower structure. The method also includes unwinding at least one continuous roll of a reinforcement material to form at least one continuous reinforcement ring member layer, the reinforcement material comprising a pultruded polymer material. Further, the method includes placing the at least one continuous reinforcement ring member layer atop the one or more printed layers of the wall of the tower structure. Moreover, the method includes printing and depositing, via the printhead assembly of the additive printing system, one or more additional printed layers of the wall of the tower structure atop the at least one continuous reinforcement ring member layer.

A lighting arrangement (10) is disclosed that comprises a plurality of solid state lighting elements (22) mounted on a grid of conductive wires (12), said grid comprising a plurality of grid segments (20) each defined by respective portions of adjacent conductive wires, each grid segment comprising a pair of reinforcement members (24, 26) affixed to said portions; and at least one said solid state lighting element mounted on said portions in between the reinforcement members of at least some of the grid segments. An apparatus and method for deforming such a lighting arrangement are also disclosed.

A lighting arrangement (10) is disclosed that comprises a plurality of solid state lighting elements (22) mounted on a grid of conductive wires (12), said grid comprising a plurality of grid segments (20) each defined by respective portions of adjacent conductive wires, each grid segment comprising a pair of reinforcement members (24, 26) affixed to said portions; and at least one said solid state lighting element mounted on said portions in between the reinforcement members of at least some of the grid segments. An apparatus and method for deforming such a lighting arrangement are also disclosed.