Embodiments of the present invention deal with stadium and arena seating structures, and in particular to seating structures which utilize a combination of concrete and metallic components.
The grandstand, stadium and arena seating industry has traditionally relied on two main types of construction to provide adequate walking surfaces, or treads, and associated riser surfaces therebetween. The first of these is a reinforced concrete system utilizing concrete for both the horizontal tread and vertical riser portions. Concrete provides excellent performance in relation to vibration, noise transfer, and deflection. However, concrete also has its drawbacks. For example, in a typical concrete system, two or three row precast pieces spanning twenty to fifty feet are poured at the factory and shipped to the jobsite for installation. The pieces include very thick reinforced concrete treads and risers. Caulk must then be used to seal the horizontal joints where the precast pieces meet and prevent water seepage. The forms needed to pour these pieces are fairly expensive and typically cannot be reused from one project to the next due to custom configurations in the seating bowl. Some systems utilize concrete treads which are poured on site, which causes other concerns regarding the unpredictability of jobsite temperature and humidity conditions in addition to the added cost of on-site concrete pouring equipment.
In addition, an all-concrete system requires that epoxy or expansion anchors be used to attach the seats or benches to the concrete treads and risers, a process that typically requires expensive field drilling and time for the epoxy to cure. The concrete system is also extremely heavy and difficult to install and requires a stronger steel or concrete understructure for support.
The other type of construction commonly used involves metallic treads and risers, often aluminum, supported by a steel understructure. The aluminum treads typically span only about six feet, and are typically supported by steel stringers positioned on six foot centers. The aluminum system provides more cost effective options for installation, final adjustment, and seat mounting, although typically cannot match the performance characteristics of the concrete system. Aluminum systems also offer more options in terms of vertical surface coloring and may be more easily modified on a project to project basis.
According to one aspect, a stadium seating construction system is disclosed. The system comprises a tiered support understructure, a plurality of tiered concrete treads, and a plurality of tiered risers. The treads are mounted to the stadium seating support understructure and have a concrete body portion, a non-concrete front embed embedded within a front end of the concrete body portion, and a non-concrete rear embed embedded within a rear end of the concrete body portion. The front and rear embeds and risers may be formed from a non-concrete material such as metal, plastic, or fiberglass.
According to another aspect, the rear embed may have an upwardly extending portion for shedding water from the upper adjacent riser.
According to another aspect, the front embed may have a first connection device. The first connection device may be adapted to interlock with a second connection device of a lower adjacent riser.
According to another aspect, the risers are arranged such that a lower portion of the riser overlaps with a forward side of the upwardly extending portion of the rear member of a lower adjacent tread.
According to another aspect, the concrete treads comprise at least one hole through which a fastener for fastening the tread to the support understructure may be inserted.
According to another aspect, the concrete treads comprise at least one non-concrete lower embed, said non-concrete lower embed having a fastener for fastening the tread to the stadium seating support understructure
According to another aspect, the front embed comprises at least one horizontal channel for receiving an upper seat fastener. The rear embed likewise comprises at least one horizontal channel for receiving a lower seat fastener.
According to another aspect, the risers further comprise at least one attachment device for attaching a seat.
According to another aspect, a stadium seating construction system is disclosed comprising a tiered stadium seating support understructure, a plurality of tiered concrete treads mounted to the stadium seating support understructure, and a plurality of tiered risers. At least one of the risers has a central vertical portion and an optional lower horizontal portion extending forward from the central vertical portion and is mounted such that the lower horizontal portion sits on top of a lower adjacent tread to achieve a water shedding effect. The risers may optionally be attached to the front end of an upper adjacent concrete tread or the rear end of a lower adjacent concrete tread using a fastener.
For the purposes of promoting an understanding of the principles of the invention, reference will now be made to the embodiments illustrated and specific language will be used to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended, such alterations, modifications, and further applications of the principles of the invention being contemplated as would normally occur to one skilled in the art to which the invention relates.
As used in the claims and specification, the term “stadium seating” refers to any tiered structure built to provide seating or standing accommodations for spectators at a sporting or other public or private event.
As used in the claims and specification, the term “seat” refers to chairs, benches or any structure upon which a person may sit and intended for use in a stadium seating structure.
In a preferred embodiment, treads 40 are placed on top of runner supports 35 such that multiple runner supports 35 are supporting each tread 40. The treads 40 are preferably comprised of individual concrete sections, each with a span of approximately six feet, although the span may be adjusted depending on the application requirements. In a preferred embodiment, the treads 40 will be pre-cast in a controlled factory environment before being delivered to the jobsite, although cast-in-place concrete may be used as well. Pre-cast treads are also easier to install and typically provide greater strength in relation to an equal size cast-in-place unit. The reduced span length also eliminates the need for prestressing.
The treads 40 may optionally include a front embed 45 and a rear embed 50 which are embedded into the front and rear portions, respectively, of treads 40 (
In order to provide a self-sealing continuous surface which will shed water and other debris and prevent seepage into the understructure, the front embed 45 may optionally comprise a connection device, shown in
In a preferred embodiment, the rear embed 50 may optionally comprise an upwardly-extending portion 85 (
It shall be understood that while the illustrated embodiment depicts an arrangement wherein the upper portion of the risers 65 interlock with the front embed 45 of an upper adjacent tread 40, other variations on this arrangement are contemplated to be within the scope of the present disclosure. For example, the front embed 45 may simply comprise a downwardly-extending lip which overlaps the front side of the upper portion of a lower adjacent riser 65 in a shingled manner. Likewise, the lower portion of the riser 65 may comprise a connection device which interlocks with a corresponding connection device within a rear embed 50 of a lower adjacent tread 40.
It shall be further understood that while the illustrated embodiment depicts two separate embeds 45 and 50 in the tread 40, the embeds 45 and 50 may actually be formed as a single member which runs from the front to the rear ends of tread 40 on the bottom or top surface of tread 40.
In certain embodiments, the treads 40 may include holes 110. Holes 110 are preferably formed when the concrete treads 40 are poured, or alternatively cut into the treads 40 at the factory. The holes 110 allow the treads 40 to be easily mounted to the runner supports 35 from the top side of the treads 40 using any appropriate fastener known in the art. In one embodiment, studs 115 may be welded to the runner supports 35, whereby the studs 115 serve as the lower portion of a fastening device (
As shown in
The lower portion of the riser 65 may optionally be attached to the upwardly-extending portion 85 or 190 of rear embed 50 or 180 using a fastener, such as screw 86. In certain embodiments, screw 86 is configured as a “tek” or self-tapping screw, although other types of fasteners known in the art may be used. Screw 86 may be used in addition to or as an alternative to bolts 75 and nuts 80. When bolts 75 and nuts 80 are not used, the riser 65 may be held in place by the male lip portion 60 (which is engaged in recess 55 or 185) and the screw 86 as shown in
In order to provide additional positional integrity of the embeds 175, 180 within the concrete portion of treads 40, the embeds 175, 180 may optionally comprise additional lips 195, 200, 205 which extend perpendicularly within the concrete tread 40 as shown in
In one embodiment, embed 300 contains a captive nut 315 which is slidably disposed within a slot 310. The slot 310 allows the nut 315 to be positioned at the proper location relative to a corresponding screw 305 when installing the tread 40. Although the nut 315 may be positioned within the slot 310, nut 315 is prevented from rotating within the slot 310 to allow the corresponding screw 305 to engage the threads of the nut 315 during installation.
Screw 305 may be implemented in a variety of forms. For example, screw 305 may comprise a separate piece which is inserted through a hole in the runner support and into the nut 315. In other embodiments, screw 305 may comprise a threaded stud which is welded to the runner support 35 with a separate nut which may be tightened against the lower surface of the embed 300 to secure the tread 40 to the runner support 35.
It shall be understood that the while the illustrated embodiment shows the embed 300 as having a female threaded nut with the screw 305 having male threads, other configurations of the embed 300 are considered to be within the scope of the present disclosure. For example, the embed 300 may comprise a male threaded screw or stud which is held captive within the slot 310 and protrudes from the slot 310 and through a hole in the understructure to engage a corresponding female threaded nut which is attached from below the understructure. In still further embodiments, the embed 300 may comprise other types of fasteners known in the art to secure the embed 300 (along with tread 40) to the runner support 35.
The described embodiments provide the noise reduction, minimized vibration and deflection, and appearance of a fully concrete system, while at the same time offering the ease of installation, mounting flexibility and lower cost of a metallic system. In addition, certain embodiments of the disclosed system allow the installation of the risers 65, 130, 220 after the installation of the concrete treads 40 is completed. This eliminates the need to have multiple crews on the jobsite at one time and allows the metallic riser portions to be shipped to the jobsite later in the project.
The disclosed system also allows the use of a durable factory-applied finish on the risers 65, 130, 220 that is typically not available for concrete. For example, the risers 65, 130, 220 may be powder coated, whereas a concrete vertical surface would typically need to be painted to achieve a similar aesthetic impression, and would still lack the durability of powder coating.
While the invention has been illustrated and described in detail in the drawings and foregoing description, the same is to be considered as illustrative and not restrictive in character, it being understood that only the preferred embodiment has been shown and described and that all changes and modifications that come within the spirit of the invention are desired to be protected.
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