Various embodiments relate generally to artificial trees, and more particularly to a mechanism for releasably securing a plurality of branch segments of an artificial tree in a stowed position.
It has become commonplace in both residential and commercial environments to incorporate plants in both indoor and outdoor spaces. Plants can serve various useful purposes, such as for example, providing decoration both for everyday and holiday occasions, as well as creating a more relaxing environment through actual and placebic effects of the plant. In cases where a live plant cannot or is preferred not to be used, artificial plants or trees can be a popular choice, such as for instance during holiday seasons. After the holiday season, the artificial tree is generally disassembled and/or moved to a storage location. Because of the large stature of the trees, disassembling and/or moving the artificial trees to a storage location can be cumbersome.
Apparatus and associated methods may relate to an artificial tree apparatus having a plurality of branch segments hingedbly connected to a trunk segment and adapted to be releasably secured in a stowed position. In an illustrative example, the branch segments may be secured in the stowed position by cinching a control member. For example, each branch segment may include a control member guide having an aperture, wherein the control member may be routed through the apertures of the control member guides for a given layer of branch segments. As the control member is cinched, the branch segments may be hinged inwardly to the stowed position. In an exemplary embodiment, the control member may include a releasable securing apparatus for retaining the branch segments in the stowed position. Releasing the control member from the cinched position may permit the branch segments to freely hinge outwardly to a deployed position.
In accordance with an exemplary embodiment, the control member may be located within a common horizontal plane as the associated control member guides. For example, the control member guides and the control member may be located along the same lengthwise portion of the branch segment to be in a common horizontal plane and at a common radius or distance from the trunk segment. In some exemplary embodiments, the control member guides may be located at mid-length location along the branch segment. In some exemplary embodiments, the control member guides may be located adjacent a proximal or distal end of the branch segments. In an illustrative example, each control member guide within a given layer of branch segments is located at a similar location along the length of the respective branch segment.
In some implementations, the control member guides may be integrally formed with the branch segments, such as for example during a manufacturing process. In other exemplary embodiments, the control member guides may be releasably connected to a pre-existing branch segment. In some exemplary embodiments, the securing apparatus may be formed in the shape of a hook to be releasably connected to a control member guide for retaining the control member in the cinched state. In other exemplary embodiments, the securing apparatus may be formed of a spring-loaded clip or clasp. In other exemplary embodiments, the control member may be formed of a zip-tie structure.
Various embodiments may achieve one or more advantages. For example, some embodiments may permit for an artificial tree apparatus to be quickly altered to a storage or stowed position from a deployed position. In some implementations, cinching the branch segments in an inwardly hinged position may permit for a decrease in required storage space for the artificial tree apparatus. In other implementations, cinching the branch segments in an inwardly hinged position may permit for a decrease in required transport space for transporting the artificial tree apparatus. In other exemplary embodiments, being able to quickly move the branch segments to a stowed position or a deployed position may increase employee productivity, such as for example when the artificial tree apparatus is used for display purposes in a business environment.
The details of various embodiments are set forth in the accompanying drawings and the description below. Other features and advantages will be apparent from the description and drawings, and from the claims.
Like reference symbols in the various drawings indicate like elements.
To aid understanding, this document is organized as follows. First, an exemplary artificial tree apparatus for retaining a plurality of branch segments in a stowed position is briefly introduced with reference to
The artificial tree apparatus 100 includes a base 105 for providing self-standing upright support of the artificial tree apparatus 100. In some embodiments, the base 105 may be secured rigidly to a floor surface. In other exemplary embodiments, the base 105 may be movable along the floor surface.
Extending vertically from the base 105 are a plurality of tree segments 110. In an exemplary embodiment, mating tree segments 110 may be removably connected to each other. The number of tree segments 110 may depend upon the overall height preference of the artificial tree apparatus 100. For example, 2-3 tree segments 110 may be used in an artificial tree apparatus 100 of lesser height and 5-6 tree segments 110 may be used in an artificial tree apparatus 100 of a greater height. In some exemplary embodiments, the length of each tree segment 110 may be the same. In other exemplary embodiments, the length of one or more tree segments 110 may be different. In other exemplary embodiments, a one-piece tree segment 110 may extend from the base 105 to a top of the artificial tree apparatus 100.
Each tree segment 110 includes a trunk segment 115 and a plurality of branch segments 120, 125. The trunk segment 115 encompasses the central or axial portion of the tree segment 110 extending vertically from the base 105. The branch segments 120, 125 are movably connected to the trunk segment 115 such as to permit the branch segments 120, 125 to move from the deployed position to the stowed position. The branch segments 120, 125 may include artificial needles or leaves to mimic a real tree. Each branch segment 120, 125 includes a proximal end adjacent the trunk segment 115 and a distal end opposite the trunk segment 115.
In the depicted example, the branch segments 120, 125 are in a first position where the distal end of each common layer of branch segments 120, 125 is positioned in a first common horizontal plane. As exemplified in reference to
Each particular layer includes branch segments 120, 125 located at common elevations. For example, a first set of branch segments 120, 125 having proximal ends located within a first common horizontal plane may be within a first layer of branch segments 120, 125. A second set of branch segments 120, 125 having proximal ends located within a second common horizontal plane may be within a second layer of branch segments 120, 125, where the first common horizontal plane is different than the second common horizontal plane. For example, the first common horizontal plane may be below or lower than the second common horizontal plane. Likewise, branch segments 120, 125 having distal ends within common horizontal planes are within a common layer. The horizontal planes may be perpendicular to a vertical axis of the trunk segment 115, for example.
Each tree segment 110 may include one or more layers of passive branch segments 120 in addition to a layer of control branch segments 125. In the depicted example, the upper tree segment 110 includes two layers of passive branch segments 120 and one layer of control branch segments 125. In other exemplary embodiments, more or less passive branch segment 120 layers may be associated with more or less control branch segment 125 layers. In other exemplary embodiments, each layer may be control branch segments 125. In still other exemplary embodiments, each layer may be passive branch segments 120 where a lower tree segment 110 has at least one layer of control branch segments 125. As exemplified and further discussed in reference to
The artificial tree apparatus 100 includes a control member guide 130 extending from each of the control branch segments 125. The control member guide 130 may be integrally formed with the control branch segment 125, examples of which are described with reference to
In the depicted example, the control member guides 130 extend beneath each control branch segment 125. In other exemplary embodiments, the control member guides 130 may extend above each control branch segment 125.
The control member guide 130 may extend from the control branch segment 125 at various locations along the length of the control branch segment 125. For example, the control member guides 130 may extend from a midway point along the control branch segments 125. In another exemplary embodiment, the control member guides 130 may extend from the control branch segments 125 adjacent the proximal end of the control branch segments 125, such as approximately 20-40% along the length of the control branch segments 125, examples of which are described with reference to
In an exemplary embodiment, each set of control member guides 130 within a layer of control branch segments 125 extend from the control branch segment 125 at a common radius relative the trunk segment 115. For example, if a first control member guide 130 is attached midway along the length of the control branch segment 125, then all control member guides 130 in the same layer may be attached midway along the length of the respective control branch segment 125.
Each control member guide 130 includes an aperture 135 for receiving a control member 140. In an exemplary embodiment, a single control member 140 is associated with an entire layer of control branch segments 125. For example, as exemplified in the depicted example, the control member 140 encircles the trunk segment 115 and is routed through each control member guide 130 within a common layer of the control branch segments 125. In an exemplary embodiment, the control member 140 is positioned within a common horizontal plane of the control member guides 130 that the control member 140 is routed through.
The control member 140 includes a body 145, an eye 150, and a securing apparatus 155. The body 145 is formed of an elongated structure suitable for extending through the apertures 135 of the control member guides 130. The body 145 is formed of a material having a suitable strength to cinch the connected branch segments 120, 125 toward a connected trunk segment 115. In the depicted example, the body 145 includes a first end having an eye 150 and a second free end having a securing apparatus 155. The free end is routed through the eye 150 to encircle the respective trunk segment 115. The securing apparatus 155 may be formed in a hook-type structure for retaining the control member 140 in a cinched or reduced diametric position, such as when the branch segments 120, 125 are pivoted to the stowed position. In an exemplary embodiment, the control member guide 130 and control member 140 may be colored to blend with the artificial tree apparatus 100, such as for example being colored green to match artificial pine needles.
When the branch segments 120, 125 reach an acceptable stowed position, the securing apparatus 155 of the control member 140 is wrapped around the branch segments 120, 125 along the body 145 of the control member 140 and hooked on a suitable aperture 135 of the control member 140 to retain the body 145 of the control member 140 in a current diametric position and thus retain the branch segments 120, 125 in the stowed position. A similar process is repeated for each layer of control branch segments 125. In an exemplary embodiment of the branch segments 120, 125 pivoting inwardly and upwardly towards a stowed position, the lowermost layer of branch segments 120, 125 is structured as control branch segments 125.
In an exemplary embodiment, the branch segment 125 is a metal rod at the time in which the loop is formed therein. In the depicted example, the branch segment 125 and integral control member guide 130 may then be coated with a covering material, such as for example plastic or polyvinyl chloride. In another exemplary embodiment, the covering material may be Teflon® manufactured by DuPont Co. In an exemplary embodiment, artificial tree needles or leaves may then be attached to the branch segment 125 and integral control member guide 130. In the depicted example, the control member guides 130 extend from the control branch segments 125 adjacent the proximal end of the control branch segments 125, such as approximately 20-40% along the length of the control branch segments 125.
The control member guide 130 may attach to any suitable artificial or real tree having movable branch segments 125 to provide a structure for moving and retaining the branch segments 125 of the artificial or real tree in a stowed position. The control member guide 130 may also be attached to the branch segment 125 along any lengthwise portion of the branch segment 125. In the depicted example, the control member guides 130 may extend from the control branch segments 125 adjacent the distal end of the control branch segments 125, such as approximately 60-80% along the length of the control branch segments 125.
In an exemplary embodiment, the second end of the control member 170 may be secured in place to retain the branch segments 125 in the stowed position. In some exemplary embodiments, each branch segment 125 may include a control member 170. In other exemplary embodiments, multiple control members 170 may be connected together, such that a user is only required to pull downwards on one control member 170 to move all of the branch segments 125 toward the stowed position. Similar to the control member guides 130, the attachment point of the first end of the control member 170 may be located at various lengthwise portions along the branch segment 125.
Although various embodiments have been described with reference to the Figures, other embodiments are possible. For example, an artificial tree apparatus may include a control member threaded through control member guides connected to each hinged branch segment in a layer of branch segments, such that by pulling on the control member or making an adjustment of the control member, all of the branch segments in the layer are hinged inwardly towards a storage or stowed position. Likewise, releasing the control member or making another adjustment of the control member from a cinched position may cause the branch segments to hinge downwardly to a deployed position. In an exemplary embodiment, a given layer of control branch segments may cause one or more layers of branch segments (e.g., passive branch segments) above the control branch segments to also hinge inwardly to the stowed position due to forcible contact with the control branch segments.
In accordance with another embodiment, a handle may attach to the free end of the control member to permit easy pulling of the free end and cinching of the control member. For example, the handle may be formed in the shape of a finger pull. In another exemplary embodiment, the handle may be removable from the free end and interchangeable with a securing apparatus. In another exemplary embodiment, the handle may include a securing apparatus.
In various embodiments, the control member may advantageously be constructed to have a low friction interface with each of the guides or any other contact points. For example, the control member may be coated with a covering material, such as for example plastic or polyvinyl chloride. In another exemplary embodiment, the covering material may be Teflon® manufactured by DuPont Co.
In accordance with another embodiment, the control member is reusable, such as for example to permit for the branch segments to be moved from the deployed position to the stowed position and back to the deployed position while using the same control member. In other exemplary embodiments, the control member may be configured for one-time use, such as for example a zip tie having a non-releasing securing mechanism. The control member may be configured to permit excess portions of the body, such as along the free end, to be cut or removed, such as when the branch segments are in the stowed position and the control member is configured for one-time use operation.
In accordance with an exemplary embodiment, the body of the control member may be formed of various structures or materials. For example, the body of the control member may be formed of an elastic rope. In another exemplary embodiment, the body of the control member may be formed of a plastic strap. In another exemplary embodiment, the body may be formed of a fabric belt or strap. Other exemplary embodiments may utilize a string, cord, or cable as the body of the control member.
A number of implementations have been described. Nevertheless, it will be understood that various modification may be made. For example, advantageous results may be achieved if the steps of the disclosed techniques were performed in a different sequence, or if components of the disclosed systems were combined in a different manner, or if the components were supplemented with other components. Accordingly, other implementations are within the scope of the following claims.
This application claims the benefit under Title 35, United States Code, Section 119(e) of U.S. provisional patent application Ser. No. 61/613,092 filed Mar. 20, 2012. The 61/613,092 application is hereby incorporated by reference into this application.
Number | Name | Date | Kind |
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4140823 | Weskamp | Feb 1979 | A |
7267852 | Rosado et al. | Sep 2007 | B1 |
Entry |
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Integrity Land Works, “Large Plants Mean Large Transplants”, 2010, p. 1-14; http://integritylandworks.com/large-plants-mean-large-trans-plants/. |
Number | Date | Country | |
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61613092 | Mar 2012 | US |