An example apparatus includes a translucent hollow body, the hollow body having an inner surface and an outer surface. The example apparatus further includes a paint layer disposed on the outer surface of the translucent hollow body. The paint layer substantially covers the outer surface of the translucent hollow body with paint, the paint layer including exposed regions having paint removed to expose the outer surface of the translucent body. At least one exposed region forms a decorative shape.

An LED light device has geometric art lighted pattern surrounding has an AC power or DC power pack incorporated with Circuit to drive LED light beam pass though decorative pieces which has geometric art, design, window, printed film, slide, holes, cutouts to form the desire geometric image, art, shape, character lighted pattern surround the LED light has the Prongs, lamp base, Battery pack to shown the lighted geometric art, image pattern surrounding the said LED light on the wall, ceiling, surface.

Apparatus and associated methods relate to an electrical interface design architecture to independently excite each of a network of light strings and/or light string controllers with any of a number of independent excitation signals. In an illustrative example, each of the light strings may receive a selected one of the excitation signals conducted via a wiring assembly to an interface formed as a plug or a corresponding socket. In some embodiments, the interface may galvanically connect one or more of the excitation signals to a corresponding load according to user-selection of a relative orientation between the plug and the socket. In some implementations the load may include a down-stream controller that draws operating power through a selected one of the conductors at the interface. In various implementations, the interface may supply a load such as a multi-channel cable or single channel light string, for example.

A power transfer system to facilitate the transfer of electrical power between tree trunk sections of an artificial tree is disclosed. The power transfer system can advantageously enable neighboring tree trunk sections to be electrically connected without the need to rotationally align the tree trunk sections. Power distribution subsystems can be disposed within the trunk sections. The power distribution subsystems can comprise a male end, a female end, or both. The male ends can have prongs and the female ends can have voids. The prongs can be inserted into the voids to electrically connect the power distribution subsystems of neighboring tree trunk sections. In some embodiments, the prongs and voids are designed so that the prongs of one power distribution subsystem can engage the voids of another power distribution subsystem without the need to rotationally align the tree trunk sections.

An apparatus comprises a wire mesh that is shaped according to an artificial foliage pattern. The wire mesh is coated with a coating to match a characteristic of the artificial foliage pattern. The coating fills in spaces between the wire mesh to produce a translucent structure in the spaces that filters light. The mesh size, mesh materials, and the type of coating, e.g., type of paint, are selected so that the coating fills in the spaces to produce a translucent structure that is thin yet strong. The thin translucent structure allows light to filter through in a natural manner. A process performs the shaping and coating of the wire mesh.

An apparatus comprises a wire mesh that is shaped according to an artificial foliage pattern. The wire mesh is coated with a coating to match a characteristic of the artificial foliage pattern. The coating fills in spaces between the wire mesh to produce a translucent structure in the spaces that filters light. The mesh size, mesh materials, and the type of coating, e.g., type of paint, are selected so that the coating fills in the spaces to produce a translucent structure that is thin yet strong. The thin translucent structure allows light to filter through in a natural manner. A process performs the shaping and coating of the wire mesh.

A lighted artificial tree includes a first tree portion including a first trunk portion, first branches joined to the first trunk portion, and a first light string. The first trunk portion has a trunk connector and a first trunk wiring assembly, the first trunk wiring assembly is electrically connectable to the first light string and the trunk connector, and at least a portion of the first wiring assembly is located inside the first portion. The second tree portion includes a second trunk portion, second branches, and a second light string. The second trunk portion has a trunk connector and a second trunk wiring assembly, the second trunk wiring assembly electrically connectable to the second lighting string and the trunk connector. The second tree portion may be mechanically coupled and electrically connected to the first tree portion by coaxially coupling the first trunk portion to the second trunk portion.

A locking artificial tree trunk including a first generally cylindrical, hollow trunk portion including an upper end, the upper end defining a notch, and a second generally cylindrical trunk portion including a body portion, a lower end having an insertable portion, and an upper end. The locking artificial tree trunk also includes a coupling mechanism having a body portion and an upper portion having a tab, and defining a channel for receiving the insertable portion of the lower end of the second trunk portion. The body portion is inserted substantially into the upper end of the first trunk portion with the tab of the upper portion aligned with the notch, thereby preventing rotation of the coupling mechanism within the upper end of the first trunk portion.

Methods and systems for making artificial flowers are disclosed. The method can include wrapping a first flower wrapper having between 1 and 5 petals around a foam core to form a first flower construct, or bud. The method can include wrapping a second flower wrapper having between 1 and 5 petals around the first flower construct, or bud. The method can include wrapping a third flower wrapper having between 1 and 5 petals around the second flower construct. The method can include wrapping additional layers of flower wrappers around flower constructs, including, but not limited to, 3 more layers of flower wrappers. Wrapping a flower wrapper around a core or a flower construct may be done manually or in an automated fashion. Wrapping a flower wrapper around a core or a flower construct may be done petal by petal or all petals simultaneously.

A gift packaging device includes a support member, a stem slidably engaged through the support member and moveable up and down relative to the support member, a carrier member disposed on the stem for supporting a gift, a number of flaps pivotally attached to the support member and rotateable relative to the support member between a folded position where the gift is shielded with the flaps, and an opened position where the gift is viewable, and a number of links are coupled between the stem and the flaps for allowing the flaps to be rotated relative to the support member between the folded position and the opened position when the stem is moved relative to the support member of the support device.