The present invention relates to a decorative sash for attaching to a Christmas tree or other tree or tree-like object. The sash is proportionally designed and constructed to spirally attach to and wrap around the tree in an ascending, or alternatively descending, and decorative manner. The sash is intended to be used primarily on its own to replace conventional Christmas tree ornaments and decorations such as balls, bells, tinsel, ribbons, and garland, but can in alternative embodiments be used in conjunction with such conventional ornaments and decorations. The sash fills a need for a convenient, time-saving tree decoration with a personal touch. The sash provides a convenient and decorative means to quickly and conveniently decorate a Christmas tree.

A no wrap strap for a string of decorative lights including a plurality of apertures within a main body and a plurality of pairs of hanging hooks extending from the main body, with each pair of hanging hooks being disposed near a corresponding aperture. The no wrap strap further includes a securing element integrally attached to and extending from one end of the main body, the securing element including a plurality of securing balls arranged along a securing string.

The invention provides an annular shroud configured to be positioned around a tree stand. The annular shroud has one or more display panels configured to display digital images about a perimeter of the tree stand. In some embodiments, the invention further includes a tree stand display assembly comprising a tree, a tree stand supporting the tree in an upright orientation, and the annular shroud around the tree stand.

Disclosed is an artificial tree having a plurality of electrified tree sections that couple together to provide power and/or command signals to devices connected thereto. One or more tree sections may have a trunk portion, one or more electrical connectors having a plurality of terminals, branches, a light string, and an electrical distribution system located at least partially within the trunk portion. A first tree section may be configured to couple to a second tree section such that an electrical connector of the first tree section is in electrical connection with an electrical connector of the second tree section, thereby mechanically and electrically connecting the first tree section to the second tree section such that power and/or the control data are transmitted to the second tree section. Further, each trunk segment may include an axial electrical connector that permits adjacent trunk segments to connect in a plurality of radial orientations relative to each other.

Apparatuses and methods for a self-deploying tree are disclosed. In an exemplary embodiment, a self-deploying tree system comprises a top tree assembly, a main tree assembly, and a base. The lower end of the top tree assembly may be coupled to the upper end of the main tree assembly, and the lower end of the main tree assembly may be coupled to the base, providing a vertical orientation of the self-deploying tree system. The self-deploying tree system further comprises a deployment mechanism which may be activated to automatically convert the tree from a collapsed configuration to a deployed configuration or from a deployed configuration to a collapsed configuration. The collapsed configuration comprises a reduced height and a reduced circumference to allow for ease of handling and storage. The deployed configuration provides for the tree to be extended to a desired height and for deployment of the limbs as desired for display.

Apparatus and associated methods may relate to an artificial tree apparatus having a plurality of trunk segments that couple together to provide a plurality of information or command signals to load devices connected thereto. In an illustrative example, one or more branch segments having light emitting devices are connected to the trunk segments to independently receive the electrical power and command signals via a control system. In some implementations, each command signal generated by the control system may include data pertaining to light color and illumination pattern. In some embodiments, each branch segment and associated light emitting devices may be independently controlled via a multi-channel arrangement. In some implementations, each group of light emitting devices may be manually configured via one or more user-interfaces. In various implementations, each trunk segment may include an axial electrical connector which permits adjacent trunk segments from being connected in any radial orientation relative to each other.

An illuminated Christmas tree decorative light control circuit includes: a main controller and at least one branch controller. The main controller includes a main control circuit, a timing circuit, a memory circuit, a RF remote control circuit and a control output circuit capable of outputting main control signals. Each branch controller includes a signal transmission circuit capable of receiving the main control signal, a connecting terminal respectively connected to a plurality of decorative light modules (LED light string/strip equipped with a plurality of LEDs arranged linearly) installed on the Christmas tree branches, and a driving circuit arranged between the signal transmission circuit and the connecting terminal. Accordingly, the decorative light module on each tree branch can be installed independently and further connected to the corresponding branch controller, followed by connecting all of the branch controllers to a main controller. Consequently, the overall wiring is more convenient and facilitated.

A multi-sectional artificial tree with internal and external power wiring for distributing and controlling power to a network of lights. The tree includes multiple tree sections, each tree section with a set of power wires inside a tree trunk, and a network of lighting wires outside the trunk. The network of lighting wires includes a tree-section wire network with a large gauge wire supplying power to groups of lights strings on branches on the tree trunk. Each group of branches has a branch-level lighting network with multiple connectors in series, and that connects to one connector of the tree-section wire network. Each branch-level lighting network powers multiple light strings connected in series, one light string per branch. The wires of the light strings are small gauge, and are connected by the branch-level connectors by a small-wire-to-large-wire connector.

Apparatus and associated methods may relate to an artificial tree apparatus having a plurality of trunk segments that couple together to provide a plurality of information or command signals to devices connected thereto. In an example, one or more branch segments having light emitting devices are connected to the trunk segments to independently receive the electrical power and command signals via a control system. In some implementations, each command signal generated by the control system may include data pertaining to light color and illumination pattern. In some embodiments, each branch segment and associated light emitting devices may be independently controlled via a multi-channel arrangement. In some implementations, each group of light emitting devices may be manually configured via one or more user-interfaces. In various implementations, each trunk segment may include an axial electrical connector which permits adjacent trunk segments from being connected in any radial orientation relative to each other.

A multi-sectional artificial tree with a tree lighting system. The tree includes a DC power converter, and lower and upper tree sections. Each tree section includes a tree frame with groups of branches and light sets in a ratio of one light set per branch. The thin, single-conductor wires of each light set are affixed only to a single branch to prevent bending and breaking. Each group of branches and light sets is positioned at a particular height on the trunk of the tree. An upper tree section includes fewer branches per group, as compared to a lower section, and thus includes fewer light sets per group. The light sets are wired in series from branch-to-branch, though the number of light sets per group varies from section to section. Consequently, a resistive load is used in the upper tree section to adjust a voltage applied to individual light sets.