US20260043241A1
SIDE-LOAD VERTICAL RAILING
Publication
Application
Classifications
IPC Classifications
CPC Classifications
Applicants
The AZEK Group LLC
Inventors
Sascha EDGE, Matthew Edward Papiernik, Christopher Hickory Tipton, Daniel E. Boss, Zhenchao Sun, Cory Richard Boudreau, David James Gennrich, Andrew Christopher Joncich, Matthew Joseph Poster, Alexandra Surasky-Ysasi, Sharon D. West
Abstract
A side load vertical railing is comprised of a top rail, a bottom rail, a spacer, and a plurality of balusters extending between the top rail and the bottom rail. The balusters are loaded into the structure by first positioning each baluster to a securing structure on the bottom rail and then pivoting the baluster into engagement with the spacer extending between adjacent vertical posts.
Figures
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001]This application claims the benefit of U.S. Provisional Application No. 63/680,970, filed on Aug. 8, 2024, which is incorporated herein by reference in its entirety.
TECHNICAL FIELD
[0002]Aspects hereof relate to a vertical railing system configured for easier installation.
BACKGROUND
[0003]A vertical railing is traditionally used in connection with decking and other surfaces as a barrier. Vertical railing is formed from a plurality of discrete balusters positioned between a top rail and a bottom rail. The assembly of individual vertical balusters between the top tail and the bottom rail is a tedious and labor-intensive task during installation.
BRIEF SUMMARY
[0004]Aspects hereof provide for a railing barrier having vertical balusters maintained between a top rail and a bottom rail. The vertical balusters are positioned between the top rail and bottom rail in a side load manner. The bottom rail and a top spacer are positioned between two vertical railing posts. The bottom rail is secured between and to the vertical posts in any suitable manner. The top spacer is also secured between and to the vertical posts in any suitable manner. The individual balusters are positioned along the bottom rail and then tilted into engagement with the spacer. The bottom rail can have any suitable structures to maintain horizontal spacing between the balusters, while also allowing the tilting of the balusters to engage the spacer so as to provide a side loading feature. The spacer also has structure for engaging the balusters as they are tilted into a vertical position from the bottom rail. The spacer can have structure for maintaining horizontal spacing between the individual balusters. The system includes a top rail that is configured to engage the spacer to secure the balusters in their vertical orientation.
BRIEF DESCRIPTION OF THE DRAWINGS
[0005]The present disclosure is described in detail herein with reference to the attached drawing figures, wherein:
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DETAILED DESCRIPTION
[0029]Aspects hereof provide apparatuses, systems and/or methods directed to a side load vertical railing structure. Specifically, a side load vertical railing is comprised of a top rail, a bottom rail, a spacer, and a plurality of balusters extending between the top rail and the bottom rail. The balusters are loaded into the structure by first positioning each baluster to a securing structure on the bottom rail and then pivoting the baluster into engagement with the spacer extending between adjacent vertical posts. The spacer has structure that holds the balusters in a spaced horizontal relationship. Once all the balusters are in place, the top rail is positioned adjacent the spacer to secure the balusters into the railing framework.
[0030]Installation of traditional vertical railing is a labor-intensive process that includes initially mounting a bottom rail between two post members or other structures. The bottom rail typically has holes precut therein to receive the balusters. After the bottom rail is installed, the individual balusters are positioned in the holes on the bottom rail. The top rail is then positioned above the upper ends of the balusters positioned on the bottom rail. The top rail also has precut holes therein that will receive the top ends of the balusters. The top ends of the balusters will have to be aligned with the holes in the top rail as the top rail is put in place between the post members. The balusters during this process are often not maintained in an exact vertical position and may in essence “flop” around in the holes on the bottom rail. This makes positioning the top rail difficult and labor intensive, often requiring two people to do the installation. The above type of installation is referred to as a “stick build” type installation. Another type of traditional installation is a “lay flat” or prebuilt installation where the balusters are positioned between a top and bottom member or rail and secured thereto, before the railing section is positioned between the vertical posts. This is also a labor-intensive process where the entire railing framework needs to be lifted into place and secured to the support posts. This can be particularly unwieldy as the rail sections can be anywhere from 6 to 10 feet long.
[0031]Aspects herein contemplate a side load vertical railing comprised of a top rail, a bottom rail, a spacer, and a plurality of balusters extending between the top rail and the bottom rail. The balusters are loaded into the structure by first positioning each baluster to a securing structure on the bottom rail and then pivoting the baluster into engagement with the spacer extending between adjacent vertical posts. The spacer has structure that holds the balusters in a spaced horizontal relationship. Once all the balusters are in place, the top rail is positioned adjacent the spacer to secure the balusters into the railing framework. The provision of the spacer in conjunction with the top rail allows the balusters to be securely held in a vertical, horizontally spaced position during installation. A single individual can install the bottom rail and the spacer between the corresponding vertical posts. The side-load nature of the structure allows the balusters to be individually pivoted into place one at a time and secured in their proper vertical and horizontal position. Once all the balusters are installed, they are permanently held in place by positioning the top rail into engagement with the spacer to effectively secure the balusters and the railing framework.
[0032]The aspects contemplated will be discussed in greater detail and with respect to the figures.
[0033]Turning to
[0034]With reference to
[0035]With reference to
[0036]As best shown in
[0037]After the top bracket 116 and the bottom bracket 118 are secured to their respective posts 112, 114, the top rail 102, bottom rail 108 and spacer 110 can be cut to the appropriate length to span the distance between the posts 112, 114. The bottom rail 108 can then be positioned between the posts 112, 114 such that the bottom rail channel 158 engages with the cross section of the brackets 118. The bottom rail 108 can be secured to brackets 118 in any suitable manner, for instance with a friction fit, or a fastener can be positioned to engage both the bottom rail 108 and the bottom bracket 118. It may also not be necessary to have friction fit or a fastener between the bottom rail 108 and the bottom bracket 118. It may be sufficient to have securement between the top rail 102 and the bracket 116 and spacer 110 to ensure the bottom rail 108 is maintained in position.
[0038]With reference to
[0039]The spacer 110 can then be positioned to extend between the post 112 and the post 114 by utilizing the brackets 116. More specifically, the upper bracket nose 160 is configured such that spacer 110 can be snapped into place between the post 112 and the post 114. In some embodiments, spacer 110 is pushed horizontally onto the bracket nose 160 so that the back vertical sidewall 132 and the front vertical sidewall 134 deflect outwardly around the bracket nose 160. In some embodiments, spacer 110 is pushed vertically onto the bracket nose 160. The flange 138 extending inwardly from the back sidewall 132 and the flange 139 extending inwardly from the front sidewall 134 snap around the bottom surface 168 of the nose 160.
[0040]Once the spacer 110 is positioned between the posts 112, 114, the balusters 104,106 can then be assembled one at time in a side load fashion. With reference to
[0041]Continuing, the top rail 102, the bottom rail 108, and the balusters 104, 106 may be formed from any materials, such as aluminum, steel, any sort of plastic or vinyl. The rails and balusters may have any cross-section shape. For example, in some aspects the rails have a “U” cross-section shape, an “H” cross-section shape, a “T” cross-section shape, and the like. The balusters can also have any cross-section shape such as rectangular, circular, or oval. The rails and balusters may be any length (e.g., 4 ft. to 8 ft.). For example, the rails may come in standard lengths, such as 2 ft., 3 ft., 4 ft., 5 ft., 6 ft., 7 ft., 8 ft., 10 ft., 12 ft., or the like.
[0042]With reference to
[0043]The balusters are side loaded in the same manner as the assembly of
[0044]The bottom channel 140 of the top rail 102 is configured to engage the spacer 180 such that the back sidewall 184 and the flange 188 pinch the upper ends 172 of the balusters 104, 106. In some embodiments, the bottom channel 140 engages spacer 180 such that a portion of bottom wall 186 aligned with slots 190 contact the upper ends 172 of the balusters. The upper rail 102 also can be secured to the bracket 116 in any suitable fashion, for instance by a screw or bolt, so as to lock the balusters 104, 106 in place.
[0045]With reference to
[0046]With reference to
[0047]Although depicted with spacer 180 engaging with the upper end 172 of the balusters (e.g., baluster 104), other configurations are contemplated. For example, and with reference to
[0048]Continuing with reference to
[0049]With reference to
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[0051]The retention body 1806 is designed to securely hold the circular baluster 200 while allowing for easy installation and removal. The C-shaped cross-section provides a natural cradle for the baluster, ensuring a snug fit and minimizing potential movement or rattling. The side wall 1902 acts as the primary support structure, while the bottom wall 1904 and top wall 1910 work together to enclose the baluster and distribute the load evenly.
[0052]The angled outer ridge 1906 and inner ridge 1908 are crucial features of the retention body 1806. These ridges may serve multiple purposes. For example, the angled outer ridge 1906 and inner ridge 1908 provide a secure attachment point for the retention insert 1808, ensuring that the insert remains firmly in place once installed. The angled design of the outer ridge 1906 allows for easier insertion of the retention insert 1808 during assembly, while also creating a locking mechanism that prevents unintended disengagement. The inner ridge 1908 acts as a stop for the retention insert 1808, ensuring proper positioning and preventing over-insertion. Together, these ridges create a channel that guides the retention insert 1808 into the correct position during installation.
[0053]The combination of the C-shaped cross-section and the ridge system allows for a modular design that can accommodate various baluster sizes and styles while maintaining structural integrity and ease of installation. This design also facilitates potential future upgrades or replacements of individual components without necessitating a complete overhaul of the railing system.
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[0056]In some aspects, the round baluster spacer 1804 may be configured to interface with the top rail 102, providing a transition between the circular baluster 200 and the top rail 102. The retention body 1806 and retention insert 1808 may be made of materials that allow for some flexibility during assembly while maintaining structural integrity when in use, such as high-density polyethylene (HDPE), polypropylene, nylon, or certain grades of polyvinyl chloride (PVC). These polymer materials provide the ideal balance of flexibility for snap-fit assembly operations while offering sufficient rigidity and durability for long-term structural performance in outdoor environments. Thermoplastic elastomers (TPEs) may also be suitable for applications requiring additional vibration dampening properties, while reinforced composites containing glass or carbon fibers can provide enhanced structural strength without sacrificing the necessary flexibility during installation. The design of the round baluster spacer 1804 may allow for easy installation of circular balusters 200 while ensuring a secure fit within the railing system.
[0057]With reference to
[0058]The square baluster spacer 2102 may include a back vertical sidewall extending downward from the top wall 2108. A front vertical sidewall may extend downward from the top wall 2108 and be spaced apart from the back vertical sidewall. In some implementations, the square baluster spacer 2102 may comprise a plurality of horizontally spaced rectangular notches formed in the front vertical sidewall.
[0059]The bottom wall 2112 of the square baluster spacer 2102 may include a plurality of slots. These slots may be positioned along the bottom wall 2112 and may be configured to receive upper ends of balusters when the balusters are tilted into a vertical position. The rectangular notches in the bottom wall 2112 may be sized to allow positioning of square balusters into their vertical positions via a side load action.
[0060]A baluster slot 2104 may be formed in the square baluster spacer 2102. The baluster slot 2104 may be configured to accommodate a square baluster 2114. In some cases, the square baluster spacer 2102 may further comprise a front flange (e.g., retention flange 2106) extending downwardly from the top wall 2108.
[0061]The square baluster spacer 2102 may include a retention flange 2106. The retention flange 2106 may extend downwardly from the top wall 2108 at various angles to accommodate different installation requirements. For example, the retention flange 2106 may extend at a 90-degree angle for maximum engagement with square balusters, at a 75-degree angle to provide some flexibility during installation while maintaining secure retention, or at a 60-degree angle to facilitate easier side-loading of balusters while still providing sufficient retention force. In some implementations, the retention flange 2106 may be configured to engage a back surface of the square baluster 2114 when the square baluster 2114 is in a vertical assembled position. The retention flange 2106 may be constructed from various materials to optimize performance characteristics, including rigid materials such as nylon, polyvinyl chloride (PVC) , high-density polyethylene (HDPE), or aluminum for maximum strength and durability. Alternatively, the retention flange 2106 may be formed from semi-flexible materials such as thermoplastic elastomers (TPEs) or polypropylene to provide some compliance during installation while maintaining sufficient rigidity to secure the balusters in their final position. In outdoor applications, the retention flange 2106 may be constructed from UV-resistant polymers or powder-coated metals to ensure long-term performance despite exposure to environmental elements.
[0062]The channel formed by the square baluster spacer 2102 may be configured to provide a friction fit with the corresponding channel of the top rail 2116. This friction fit may help secure the square baluster spacer 2102 in place within the railing system.
[0063]In some cases, the square baluster spacer 2102 may be constructed from flexible materials such as thermoplastic elastomers (TPEs), polyethylene, polypropylene, or flexible PVC compounds that provide sufficient resilience during installation while maintaining structural integrity when in use. These materials offer the advantage of allowing slight deformation during the side-loading process, then returning to their original shape to securely hold the balusters in place. Silicone-based polymers and certain rubber compounds may also be suitable for applications requiring enhanced vibration damping properties. In some embodiment, square baluster space 2102 may be constructed from metal. The dimensions of the square baluster spacer 2102 may vary based on the specific requirements of the railing system in which it is used.
[0064]The square baluster spacer 2102 may contribute to the overall assembly of the railing system by providing a secure interface between the top rail 2116 and the square baluster 2114. The retention flange 2106 and the baluster slot 2104 may work together to maintain the square baluster 2114 in its proper vertical orientation within the railing system.
[0065]From the foregoing, it will be seen that this disclosure is one well-adapted to attain all the ends and objects hereinabove set forth together with other advantages which are obvious, and which are inherent to the structure. It will be understood that certain features and subcombinations are of utility and may be employed without reference to other features and subcombinations. This is contemplated by and is within the scope of the claims.
[0066]While specific elements and steps are discussed in connection to one another, it is understood that any element and/or steps provided herein is contemplated as being combinable with any other elements and/or steps regardless of explicit provision of the same while still being within the scope provided herein. Since many possible embodiments may be made of the disclosure without departing from the scope thereof, it is to be understood that all matter herein set forth or shown in the accompanying drawings is to be interpreted as illustrative and not in a limiting sense.
[0067]As used herein and in connection with the claims listed hereinafter, the terminology “any of clauses” or similar variations of said terminology is intended to be interpreted such that features of claims/clauses may be combined in any combination. For example, an exemplary clause 4 may indicate the method/apparatus of any of clauses 1 through 3, which is intended to be interpreted such that features of clause 1 and clause 4 may be combined, elements of clause 2 and clause 4 may be combined, elements of clause 3 and 4 may be combined, elements of clauses 1, 2, and 4 may be combined, elements of clauses 2, 3, and 4 may be combined, elements of clauses 1, 2, 3, and 4 may be combined, and/or other variations. Further, the terminology “any of clauses” or similar variations of said terminology is intended to include “any one of clauses” or other variations of such terminology, as indicated by some of the examples provided above.
[0068]The following clauses are aspects contemplated herein.
[0069]Clause 1. A railing system comprising: a top rail; a spacer positioned adjacent the top rail; a bottom rail; a plurality of balusters extending between the top rail and the bottom rail; wherein the bottom rail has a plurality of securing structures for horizontally securing a bottom portion of each baluster while allowing tilting of the baluster to a vertical position; and wherein the spacer has a plurality of slots that receive the upper ends of the balusters when they are tilted into a vertical position during assembly.
[0070]Clause 2. The railing system of clause 1, further comprising a plurality of plugs positioned along the bottom rail and engaging a bottom portion of the balusters to allow the balusters to be tilted into a vertical position.
[0071]Clause 3. The railing system of clause 2, wherein the bottom rail has a plurality of holes for engaging a first portion of the plugs.
[0072]Clause 4. The railing system of clause 3, wherein each plug has a second portion for engaging a lower end of the baluster.
[0073]Clause 5. The railing system of clause 1, wherein the top rail has a channel that engages the spacer along its length to hold the balusters in place.
[0074]Clause 6. The railing system of clause 1, wherein the slots in the spacer are positioned along a front vertical sidewall of the spacer.
[0075]Clause 7. The railing system of clause 1, wherein the balusters are of a circular cross section, and the railing system further comprises a buffer strip extending along the spacer to prevent rattling of the circular balusters.
[0076]Clause 8. The rail system of any of clauses 1-5, wherein the slots in the spacer are positioned along a bottom wall of the spacer.
[0077]Clause 9. The rail system of any of clauses 1-8, wherein the balusters are of a square cross section.
[0078]Clause 10. The rail system of any of clauses 1-9, wherein the balusters are of a circular cross section.
[0079]Clause 11. The rail system of clause 10, further comprising a buffer strip extending along the spacer to prevent rattling of the circular balusters.
[0080]Clause 12. The railing system of clause 11, wherein the buffer strip is a rigid and fixedly engages the circular balusters.
[0081]Clause 13. A round baluster spacer for use in a railing system, comprising: a retention body having a generally C-shaped cross-section forming a channel to receive a circular baluster, the retention body including a side wall, a bottom wall, and a top wall; an angled outer ridge and an inner ridge formed on the retention body; and a retention insert configured to cooperatively engage with the retention body, the retention insert including a bottom flange extending along an inner surface of the bottom wall of the retention body, a side flange extending upward from the bottom flange, and a clip portion configured to engage between the inner ridge and the angled outer ridge of the retention body.
[0082]Clause 14. The round baluster spacer of clause 13, wherein the retention body further comprises a baluster slot configured to receive the circular baluster.
[0083]Clause 15. The round baluster spacer of clause 14, wherein the retention body further comprises a retention slot configured to receive the retention insert.
[0084]Clause 16. The round baluster spacer of clause 15, wherein the clip portion of the retention insert is configured to snap-fit between the inner ridge and the angled outer ridge of the retention body.
[0085]Clause 17. The round baluster spacer of clause 16, wherein the retention body and the retention insert are made of materials that allow for flexibility during assembly while maintaining structural integrity when in use.
[0086]Clause 18. The round baluster spacer of clause 17, wherein the retention body is configured to interface with a top rail of the railing system, providing a transition between the circular baluster and the top rail.
[0087]Clause 19. The round baluster spacer of clause 18, wherein the retention body and retention insert cooperatively form a secure mounting system for the circular baluster that allows for easy installation while ensuring a secure fit within the railing system.
[0088]Clause 20. A square baluster spacer for use in a railing system, comprising: a top wall; a vertical sidewall extending downward from the top wall; a bottom wall extending horizontally from the sidewall and spaced apart from the top wall; a plurality of horizontally spaced rectangular notches formed in the bottom wall; and a downwardly extending flange on the top wall configured to engage a surface of a square baluster when the square baluster is in a vertical assembled position.
[0089]Clause 21. The square baluster spacer of clause 20, further comprising an upwardly extending flange from the bottom wall.
[0090]Clause 22. The square baluster spacer of clause 21, wherein the top wall, vertical sidewall, and bottom wall form a channel configured to engage with a corresponding channel in a top rail of the railing system.
[0091]Clause 23. The square baluster spacer of clause 22, wherein the channel formed by the square baluster spacer is configured to provide a friction fit with the corresponding channel of the top rail.
[0092]Clause 24. The square baluster spacer of clause 23, wherein the rectangular notches in the bottom wall are sized to allow positioning of the square balusters into their vertical positions via a side load action.
[0093]Clause 25. The square baluster spacer of clause 24, wherein the downwardly extending flange on the top wall is configured to engage with the back surface of the square baluster when a top rail is snapped into place over the square baluster spacer.
[0094]Clause 26. A method of assembling a railing system including a bottom rail, a top rail, a spacer and a plurality of balusters, the method comprising: positioning a baluster on the bottom rail in a non-vertical orientation; tilting the balusters to a vertical orientation such that they engage the spacer; and positioning the top rail onto the spacer to secure the balusters.
[0095]Clause 27. The railing system of clause 26, further comprising positioning plugs along the bottom rail to secure the lower ends of the balusters.
[0096]Clause 28. The railing system of clause 27, further comprising positioning laterally spaced slots on the spacer to receive the upper ends of the balusters.
Claims
What is claimed:
1. A railing system comprising:
a top rail;
a spacer positioned adjacent the top rail;
a bottom rail;
a plurality of balusters extending between the top rail and the bottom rail;
wherein the bottom rail has a plurality of securing structures for horizontally securing a bottom portion of each baluster while allowing tilting of the baluster to a vertical position; and
wherein the spacer has a plurality of slots that receive the upper ends of the balusters when they are tilted into a vertical position during assembly.
2. The railing system of
3. The railing system of
4. The railing system of
5. The railing system of
6. The railing system of
7. The railing system of
8. A round baluster spacer for use in a railing system, comprising:
a retention body having a generally C-shaped cross-section forming a channel to receive a circular baluster, the retention body including a side wall, a bottom wall, and a top wall;
an angled outer ridge and an inner ridge formed on the retention body; and
a retention insert configured to cooperatively engage with the retention body, the retention insert including a bottom flange extending along an inner surface of the bottom wall of the retention body, a side flange extending upward from the bottom flange, and a clip portion configured to engage between the inner ridge and the angled outer ridge of the retention body.
9. The round baluster spacer of
10. The round baluster spacer of
11. The round baluster spacer of
12. The round baluster spacer of
13. The round baluster spacer of
14. The round baluster spacer of
15. A square baluster spacer for use in a railing system, comprising:
a top wall;
a vertical sidewall extending downward from the top wall;
a bottom wall extending horizontally from the sidewall and spaced apart from the top wall;
a plurality of horizontally spaced rectangular notches formed in the bottom wall; and
a downwardly extending flange on the top wall configured to engage a surface of a square baluster when the square baluster is in a vertical assembled position.
16. The square baluster spacer of
17. The square baluster spacer of
18. The square baluster spacer of
19. The square baluster spacer of
20. The square baluster spacer of