1. Field of the Invention
The present invention relates generally to guardrail stanchions, guardrail systems and methods of affixing stanchions, and more specifically to stanchions, guardrail systems and methods for use on construction sites, and particularly to stanchions, guardrail systems and methods for use on concrete structures.
2. Background Information
Several guardrail devices are known that allow for safety protection at the edge of a construction, such as guardrails placed to prevent workers or objects from falling off the edge of a building under construction. Some form of protective barrier or guardrail is usually required around the edges of the workplace. Detailed regulations are established by various bodies designed to eliminate or reduce workplace hazards. Organizations such as the Occupational Safety and Health Administration (OSHA) in the United States and various state agencies, Workmen's Compensation Boards and trade organizations often require some form of barrier protection in the workplace. Non-U.S. governments, or organizations within such governments, may also require barrier protections at workplaces. Even if OSHA or other regulatory bodies do not require such systems, or where requirements for barrier protection are lax or less stringent (such as may be the case from jurisdiction-to-jurisdiction or country-to-country), insurance companies would insist upon the best safety or provide incentives for use of best practices.
In the United States, OSHA has established construction standards for guarding open-sided floors and roofs, including erection of a “standard railing”, which comprises a top rail, intermediate rail, toeboard and posts, to enclose such open spaces. The top rail is required to have a vertical height of approximately 42 inches from the upper surface of the top rail to the floor, platform, runway or the like being protected. The intermediate rail is specified to be halfway between the top rail and the floor, etc., while the toeboard is required to be at least 4 inches in vertical height from its top edge to the level of the floor, platform, etc. In addition, the toeboard must be securely fastened in place and must be flush with the floor such that not more than a ¼-inch clearance exists between the toeboard and the floor. An assembly so constructed is sometimes referred to as a “standard railing”. Similar regulations may be present in countries outside of the United States.
Various attempts have been made to provide construction guardrail systems, some of which may or may not be considered “standard railings”. One such guardrail system involves use of a support stanchion as shown in U.S. Pat. No. issued to Brand on Apr. 5, 1977, for supporting a life line around the perimeter of an elevated area such as a building roof. The stanchion is anchored to the roof or building support by bolts or screws embedded into the floor. Another system includes use of a support as shown in U.S. Pat. No. 5,560,588, issued to Hilliard, for a temporary guard railing erected along the edges of open floors, balconies, stairs, and the like in a building under construction. This device is secured to the floor surface by running screws or other male connectors through the support and into the floor surface. Connecting devices to the floor of a structure, such as by nailing a standard or stanchion to a concrete floor results in damage to the floor, often requiring expensive or time-consuming repair, among other problems.
Further safety railing systems or stanchions for concrete slab walls are shown in U.S. Pat. No. 5,377,958 to Palmer, and U.S. Pat. No. 6,547,223 to Letourneau. The device in Palmer involves vertically extending stanchion members mounted to wall brackets, which the brackets in turn are mounted below the exterior facia of the wall by fasteners driven through the brackets into the underlying wall structure. The device in Letourneau involves a railing that engages in a cavity of an anchor where the anchor is rigidly mounted into the concrete wall panel at a face or end of the floor slab. Here again, such systems have fasteners that are driven into or imbedded within the concrete or floor structure. These systems also cover an edge area of the flooring which must be removed in order to finish the edge or the areas adjacent the edge.
A further system as shown in U.S. Pat. No. 6,270,057 issued to Highley et al., involves a system for use on a structure where concrete is poured upon corrugated material. The reusable multi-story building construction guardrail system includes a bar element bolted to an outside of a frame member that forms the outer perimeter of a conventional elevated slab floor support structure consisting of I-beam floor joists and trusses that serve to support horizontal floor supports and the corrugated floorpan thereabove onto which concrete is poured in order to form an elevated concrete slab floor surface in a multi-story building. The protection system is bolted directly to the perimeter frame member or support structure upon which the concrete is poured. Yet a further system as shown in U.S. Pat. No. 4,909,483 to van Herpen involves a handrail support which is kept in place by a weight element placed upon a base. The simplicity and usefulness of the present invention in this application is neither taught nor suggested by these mechanisms.
A number of guard rail mechanisms for which patents have been granted, also relate to the “slab-grabber” or clamping variety. Some examples of such devices are found in U.S. Pat. No. 4,669,577 to Werner; U.S. Pat. No. 3,995,834 to Melfi; U.S. Pat. No. 3,881,698 to Marsh; U.S. Pat. No. 3,863,900 to Dagiel et al.; and, U.S. Pat. No. 7,234,689 to Kuenzel. These devices are typically clamped to the edge of a slab of the construction. They generally mimic a C-clamp mechanism which compresses upon the top and bottom sides of a slab, while also covering an edge portion of the slab to which the clamp is attached. While the clamping action avoids damage to the floor element, being that it is attached at the edge necessarily requires a subsequent movement of the device in order to work on the structure at that edge of the slab. The simplicity, reliability and usefulness of the present invention in this application in not taught nor suggested by these slab grabber mechanisms.
Various other mechanisms for which patents have been granted relate to other types of compression-fit or friction-fit mechanisms. An example of such device is found in U.S. Pat. No. 3,662,993 to Lionetto. In such application, posts span from the floor to ceiling and are fastened into position with jacks or threaded bars. While such mechanisms generally avoid direct damage to the floor or structure, and also avoid placement or coverage over the edge of the slab, the reliability of such compression-fit mechanisms is questioned. Natural or unnatural changes, such as expansion or contraction of the structure materials, present concern due to slippage of the devices from a secured safety position within the bay of the structure. Similar expansion or contraction or other changes to the device itself may also occur. The material used for the device is different than the concrete or other material that is used for the structure, and the expansion and contraction characteristics are different such that the materials expand and/or contract at different rates. Such differences in the material characteristics of the device and structure present further variability issues for the stability of a compression-fit system. As the structure or device expands or contracts, the compression-fit forces are changed. The changed forces may cause the device to break, or to slip or weaken its fit against the structure, or if the device does not yield, in an extreme case the structure may shift or crack. In some instances a post is also used as (or has the effect of being used as) a shoring or re-shoring device. A shoring device is commonly understood to be a device which supports or holds the form or deck, as opposed to a re-shoring device which holds or supports the resulting concrete structure. In either case, the expansion of the device might lift the ceiling slightly, thereby causing other posts or shoring devices to loose their compression fit. In some cases the posts fall from position and are otherwise unworkable as a safety device. In sum, the compression-fit devices having a post span from floor to ceiling are inherently suspect and unworkable for use in a safety role. By the same token, compression-fit posts that span from wall-to-wall are also unworkable.
Other friction-fit mechanisms for which patents have been granted include U.S. Pat. No. 3,589,682 to Dickey granted Jun. 29, 1971, and U.S. Pat. No. 3,439,898 to Cleveland et al granted Apr. 22, 1969. Dickey says that the general practice at the time in erection of such safety fences involved use of lengths of 2-by-4 lumber cut to approximately the spacing between the floor and ceiling, and wedged into place in any expedient manner. One or more horizontal rails were commonly nailed to such vertical pieces of lumber to construct a crude fence. In practice it was found that the wedging of such vertical pieces of lumber can never be made completely secure and the lumber will rapidly dry out, being exposed to very severe weathering, and will become loose and sometimes blow away altogether causing an additional hazard to persons standing below. The same thing can occur merely because the concrete itself dries out and will shrink very slightly thereby causing such vertical pieces of lumber to become loose and fall (or in other cases, cause the lumber to tighten or result in bowing or nail pulls). The appearance of the otherwise safe structure may cause a false sense of security, further exacerbating the hazard. Dickey uses a telescoping column for erection of a safety fence or guardrail at a building under construction. A manually operable jacking system is used for extending the column and forcing upper and lower pads firmly against the ceiling and floor of the building to hold the column firmly in position. Cleveland also shows a compression-fit safety barrier and barrier fence having telescoping columns. Such telescoping compression-fit systems may be positioned so as to not obstruct the edge of the flooring and may reduce the potential for direct damage to the structure (such as damage that might otherwise be caused by nailing). However, such systems lack the simplicity and reliability of the present invention. They also are subject to variables encountered with material expansion as noted above, and thus are suspect and unreliable for a safety role. Further, improvements are always desired in any art. Other drawbacks of such friction-fit mechanisms include the cost of having columns span from floor-to-ceiling or having expensive threaded components or other means for telescoping action. Precautions are also required to prevent screw-type mechanisms to not loosen, or such mechanisms may require a special tool such as a wrench or other tool to set-up or extend the apparatus for a friction fit. The size of the floor-to ceiling mechanisms are bulky and often troublesome to transport and/or store. Further, the over-tightening of a post or column may result in damage to the floor or ceiling and corresponding loosening of adjacent posts or columns. Such mechanisms are generally troublesome to set-up.
Disadvantageously, while the above and other past approaches may be sufficient in some respects for their particular purposes, each has deficiencies. Some of the approaches require a considerable effort in set-up and take-down; or still result in damage to the structure (such as by nailing, which commonly requires drilling or use of a hammerdrill or other aggressive tools) which in turn requires additional expense, delay and labor for correction; or connect adjacent to, or cover up, the edge of the structure thus requiring subsequent movement in order to work on or at the edge location; or rely on a compression or friction fit which is susceptible to slippage and other troubles as mentioned. Further, with such approaches there is an ever-present uncertainty as to whether the systems are indeed compliant with OSHA or other requirements, or if initially compliant, whether they can maintain compliance and be safe throughout the construction effort. Since the temporary safety mechanisms are typically repeatedly moved in order to undertake construction efforts, workers (and the owners of the structures) must be diligent in assuring that the systems continue to be safe. Even if some of the prior systems comprise a “standard railing” and/or guardrail system that securely connects to the structure without nailing or other damage to the structure, they are either of a compression-fit variety, or disadvantageously cover the edge location of the flooring.
The known guardrail devices are often complicated, expensive, typically result in damage to the structure to which they are affixed, are difficult to secure, and are susceptible to non-compliance with OSHA. Many are not reusable, many are limited to a particular site configuration, require temporary removal and re-setting when a forklift needs access, are in the way when working on an outside edge of the structure (such as when laying brick or pouring outside edge wall or constructing outside edge wall), require the subsequent patching of holes or damage to the structure or require rework of concrete that was damaged by a nail gun or drill or other anchor mechanism. A crew of workers is typically required to assemble guardrails (spending time and labor that could otherwise be devoted to working on the actual structure as opposed to a temporary safety system that will be obsolete upon completion of the construction.
While some of the known guardrail devices are connected to the edge of a concrete deck by friction or grabbing mechanisms, others are mounted into the deck or walls with bolts or nails (or use anchors that are affixed within the structure), or use weights to hold the guardrail adjacent an edge of the deck. Workers will erect one of the many known devices or systems (or cobble together a solution for a given customized fix) and deal with the follow-up or related tasks as needed. For instance, workers will patch holes that were created when nails or other fasteners were removed from the deck. Workers will move a railing from an edge so that the edge area may be cleared for finishing or treated with additional building materials. The railing may be temporarily removed to allow a fork lift to place materials on the deck, and then reassembled or nailed back into position. Workers may also take special care to not lean too hard against a rail held down by weights, or take care not to fasten a life-line to the guardrail, or to undertake one of many other tasks or precautions due to the nature of the known devices or systems.
Damages made to the walls of a structure have become increasingly problematic in recent years especially since owners of the structures sometimes prefer to keep the raw walls exposed to view for aesthetic purposes. Until somewhat recently, drilling into a wall to fasten a board or other safety mechanism was not considered a problem since the walls would typically be covered with paint or sheetrock or other materials. Drilling into the floor or walls or ceilings creates unsightly marks, and the repairs are often unsatisfactory. Further, with a preference for having exposed walls, an emphasis is often placed on positioning conduit within the walls. Thus, drilling into the walls becomes risky. Indeed, safety mechanisms are required to be used on a project, so the workers and owners often have to deal with the competing goals of safety vs. appearance and costs.
The known guardrail mechanisms indeed have several shortcomings as referenced above. Such shortcomings require extra steps or precautions. Workers and developers or owners of the structures have not so much seen these shortcomings (and the required extra steps or precautions) as problems but, rather, a fact of life or part of the job at hand.
The present inventors, however, have recognized that mounting the guardrail device and related stanchion items adjacent the edge of the deck or other opening of the structure by using means other than a compression-fit that covers the edge, and not having to accommodate for nailing or bolting of the stanchions into the concrete wall or deck, while utilizing a pre-existing feature of the structure that requires little or no extra preparation, planning or expense, would provide numerous benefits. For instance, such a system would enable guardrails to be securely fastened to a bay of a concrete construction without having to subsequently remove the guardrails in order to work on or about the edge of the slab, and would enable fast removal and set-up of a temporary guardrail. Such a system would also avoid damage to the structure otherwise caused by nails or other fasteners, thus lessening or eliminating the need to make expensive or unsightly repairs to the concrete structure. Instead of throwing away a temporary guardrail mechanism that is custom built for each bay, such a system would enable re-use for subsequent projects, and would provide uniformity of guardrail systems from bay-to-bay and project-to-project. Thus, less set-up time and training are required, and waste is reduced. A guardrail system that is easy to set-up or remove, and which requires no additional patching or repair of concrete, reduces labor costs and overall costs of construction. Time and expense otherwise devoted to set-up and maintenance of a temporary safety mechanism can instead be devoted to the tasks of constructing the actual or permanent structure, thus efficiently using resources and multiplying cost savings and speed of construction. In addition, a system that accomplishes these and other tasks while at the same time assisting or assuring compliance with OSHA regulations or insurance or other standards, is especially desired and beneficial. The peace of mind that such a system is safe has a lasting positive impact on workers and the developers or owners of the structure. These and other benefits as recognized by the present inventors are described further below.
The present inventors have also recognized that having a guardrail stanchion also operate as a life-line anchorage would provide further benefits. Traditional guardrail mechanisms have not been secure enough to accommodate such use. Further, OSHA requires that life-line anchorages be independent of any mechanism being used to support or suspend platforms of the structure. Thus, traditional floor-to-ceiling or shoring mechanisms might not be acceptable for use as a life-line anchorage. The mere presence of unstable yet seemingly safe shoring mechanisms may result in an unfortunate instance of a worker unwittingly or improperly using such systems for life-line purposes. Having a guardrail stanchion that also accommodates life-line anchorage thus reduces such risks and also provides a less expensive alternative to traditional anchorage mechanisms.
Heretofore unrelated to the use or set-up of “standard railing” and/or guardrail systems is the formation of the walls of a structure. In common applications, multiple walls together with a deck/ceiling are combined to create a structure having multiple rooms or “bays”, such as used for the rooms of a high-rise apartment building or hotel. Known methods for forming a concrete wall include the use and set-up of forms into which is poured concrete which hardens to form a wall of the structure. The forms include panels which are fastened together with “ties” that extend from one panel to another panel. The ties restrict the panels from separation which would otherwise occur due to pressure caused by pouring of the concrete. After the concrete hardens, the ties are removed or extracted from the forms in order to remove or disassemble the forms. Removal of the ties results in a through-hole in the wall. The resulting through-holes are filled or patched in order to provide a smooth finished surface (and soundproofing and/or fireproofing) of the bay. The present inventors, however, have recognized that utilizing such a pre-existing through-hole would provide great benefit, enabling secure fastening of a guardrail stanchion or guardrail system and overcoming the problems with previous systems.
In accordance with the invention, then, the problem of securing a guardrail stanchion adjacent the edge of a deck under construction without damaging the deck or walls of the bay is solved by utilizing at least one through-hole of a concrete wall to affix a guardrail stanchion to the concrete wall. In this way, a stanchion may be securely affixed to the wall within the bay without reliance upon a compression-fitting, without obstructing the edge of the deck, and without damage to the deck. Such stanchion may also double as a life-line anchorage.
Particular optional embodiments of the invention may include insertion of a fastener through the through-hole. The fastener may optionally include a threaded pin and a corresponding nut. Also in particular embodiments, the system may include utilizing at least two through-holes, and the stanchion may include at least two openings each capable of receiving a fastener which extends through a corresponding through-hole. The stanchion may optionally be an elongated member having at least two elongated slots. The elongated member may be positioned generally vertically within the bay, and may receive fasteners through through-holes. The through-holes may be generally aligned in a vertical fashion on the wall. In a particular advantageous embodiment, a through-hole is a tie-hole. A through-hole may optionally be some other through-hole of the wall. Each of these details provides particular advantages and can be implemented independently of the others.
Particular embodiments of the invention may also include another stanchion affixed to an opposite wall, and a guardrail may be affixed to, and extend between, the two stanchions. The stanchion can receive any number of guardrails. Three guardrails are the most advantageous, however. In further optional aspects, a guardrail may include a cable affixed to a stanchion. Further particular embodiments of the invention include a stanchion which may optionally include a life-line ring or anchorage. Here again, each of these details can be implemented independently of the others.
The above summary of the present invention is not intended to describe each illustrated embodiment, aspect, or every implementation of the present invention. The figures and detailed description that follow more particularly exemplify these and other embodiments and further aspects in accordance with the principles of the invention.
While the invention is amenable to various modifications and alternative forms, specifics thereof have been shown by way of example in the drawings and will be described in detail. It should be understood, however, that the intention is not necessarily to limit the invention of the particular embodiments described. On the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention and as defined by the appended claims.
Among the guardrail systems known in the prior art are those referenced in the background section, above, as well as the example as shown in
As shown in
A series of supports 540 are typically configured within a single bay 530. Applicants have seen different types of supports and mechanisms included in conjunction with supports 540, such as supports 580 of the “slab grabber” variety (some of which are referenced above in the background section), or one of many other supports. Workers at a construction site may mix and match varieties of supports or systems to fashion the temporary barrier. In some cases, the barrier is handmade from available materials at the location, or includes devices such as slab grabbers or other mechanisms to supplement a cobbled-together solution. Such a cobbled-together “system” varies from project to project, even from bay to bay, and in practice, there is rarely uniformity of such custom built systems. After the supports 540, 580 are positioned, rails 570 are connected between supports 540, typically by nailing rails 570 to a face 560 of support 540. Rails 570 might also extend from supports 540 located in adjacent bays, i.e., extend from bay 530a to bay 530b. Rail 570 extends across bay 530a to bay 530b by overlaying wall edge 525b. Rail 570a abuts rail 570b at bay 530b. In a case were a slab grabber 580 is used, the opposite end of rail 570a abuts wall 520, and rail 570c is nailed to rail 570a. Use of slab grabber 580 typically requires rail 570a to be slightly inset from the edge wall 525. In some cases, a two-by-four or other material or stud 590 will be nailed or secured to the inside of wall 520a so that rail 570a can be secured to the structure 500. Here again, nailing stud 590 into wall 520a results in damage to the wall, potentially requiring patching and the hazards and expenses mentioned above. Even in cases where all supports 540 are of a similar variety (i.e., in cases where only supports 540 are used, or where only supports 580 are used, or where only supports of some other variety are used), variations in the arrangement of the fall protection mechanism are common, such that workers are rarely able to maintain uniformity from bay-to-bay. In essence, each bay receives a custom-built guardrail system.
The guardrail system of
Supports 540 as shown in
A guardrail system is a temporary barrier that typically must also be periodically moved in order to supply materials to the bay (in addition to the requirement of being moved to conduct edge finishing). In a typical construction, a guardrail system must be at least temporarily removed in order to allow a forklift or crane carrying construction materials to be “flown” into the bay. The forklift or crane is use to supply pallets of materials used for further construction of the site. Thereafter, the guardrail needs to be re-assembled for safety purposes. In cases where the supports 540 are nailed into position, the process of removal and reassembly can be significant. Such action increases the labor costs and increases damage and debris due to repeated nailing or securing of the supports 540 to the slab 510. Further, and depending on how the system has been cobbled together, opening one bay 530a for receipt of materials might impact the guardrail mechanisms of other bays. Since materials need to be regularly supplied to the respective bays, the dealing with guardrails and attending to the recurring difficulties has been considered a typical burden or requirement of the job.
Other systems run rope or cables from one wall of a bay to the other wall. In some cases, a rope or cable will pass through walls in order to accommodate use for multiple bays. Maintaining sufficient tension of the cable in order to reduce or eliminate unacceptable sag is often a problem with such cable systems. Further, shut-down or take-down of the cable at one of the bays typically results in take-down of the cable from adjacent bays. Thus, loading a bay with construction materials may typically result in a hazard at adjacent bays which are at least temporarily not in compliance with safety standards or best practices.
The system of
Many of the known guardrail or stanchion systems, including the example of
Heretofore unrelated to the use or set-up of a “standard railing” or guardrail system is the formation of the walls of a structure.
Panels 553 are typically substantially rigid panels typically made of steel and having a generally rectilinear shape of a desired wall dimension. Panels 553 may also be made of other materials such as wood or plastic or metal or composites of alternative materials. Various panel systems 550 are available for pouring such structures. In one such system manufactured by Outinord, a model TMPH 80 is a basic panel having a dimension of about 2500 mm in width and 2345 mm in height. The TMPH 80 basic panel has a corrugated type of structure on one side with a smooth surface on an opposite side (the smooth surface side is the side where the concrete is poured). Whalers (not shown) or other re-enforcement members typically run horizontally along the corrugated side of the panel 553. Holes are provided within the whalers or re-enforced areas for receiving ties (ties described below). A panel 553 typically includes at least 4 holes for receiving ties. With the TMPH Model 80, two holes are typically positioned within whalers at about 16 inches from the bottom edge of panel 553, each inset approximately 625 mm from either end, leaving a span of approximately 1250 mm between the two holes. Another two holes are positioned within a whaler approximately 5 feet 8 inches from the bottom edge of panel 553 and have a similar spacing as compared to the lower two holes.
Once a pair of panels 553a, 553b, are positioned in opposing relationship as generally shown in
In operation of the heretofore unrelated wall-forming techniques, concrete or other similar substance is poured into and onto form system 550. Concrete fills the spaces A and areas atop the deck panel to create a formed wall and corresponding ceiling/slab structure when the concrete or other substance hardens. The ceiling of one bay functions as the floor of an upper bay. Once the concrete has hardened, and usually the following day, the form system 550 is removed. The system 550 is then reset at another location on the project to form additional walls, ceilings/slabs and bays. Removal of wall form 552 includes removal of ties 575. The removal of a tie 575 results in a tie-hole 576 (see
In some instances, as shown in
A sleeve 578 may also be placed at different positions to assist with the construction effort, such as positioning at various locations to accommodate “outrigging” which is positioned on the outside of structure 500. Outrigging is used in order to construct the end walls (not shown) of a structure 500. Outrigging may include a platform which hangs off the end of the structure and allows workers to position themselves to set forms. The outrigging may also support the additional forms to be placed for the pour of the subsequent level. While not shown, a tie may be inserted through a sleeve in order to secure a “bucket” to the exterior of the structure. The bucket is positioned to hold a console pignion or “outrigging” end wall platform at the exterior wall of the structure. In some cases, a tie-hole 576 of an exterior wall may also be used to assist in stabilizing the outrigging.
There are a variety of different ties 575, some of which include ties of the taper-tie variety, or flat-tie variety. A taper tie is tapered to allow for easier removal of the tie when the concrete hardens. A tie 575 usually includes threads at one end, and some ties are threaded at both ends. Usually a tie receives a nut (such as a wing-nut or other nut) to tightly secure the panels 553 into position. Ties 575 come in various lengths, any of which may be used depending on the desired thickness of the resulting wall to be poured. The ties 575 and panels 553 are configured such that when a nut is fully tightened upon a tie, the panels 553 are precisely spaced. With such systems, and as long as the ties are fully tightened, there is no need to measure the distance between panels. A typical tie 575 has a diameter of approximately 1 1/16 inches (although other dimensions may be used). Such wall forming systems have been used for years.
The known guardrail mechanisms have several shortcomings as referenced above, including those resulting from nailing into the concrete structure, or covering the edge of the deck in the case of a slab-grabber mechanism. As noted above, it remained for the present inventors to recognize that mounting the guardrail device and related stanchion items adjacent the edge of the deck or other opening of the structure by using means other than a compression-fit that covers the edge, and not having to accommodate for nailing or bolting of the stanchions into the concrete wall or deck, while utilizing a pre-existing feature of the structure that requires little or no extra preparation, planning or expense, would provide numerous benefits as describe herein. It remained for the present inventors to develop a guardrail system that utilizes an aspect of the heretofore unrelated system of wall formation, namely, utilizing a through-hole produced from the concrete wall forming techniques. The through-hole contained in the wall of a bay of the structure is used to affix a guardrail stanchion. Utilizing a through-hole allows securing of a guardrail stanchion without harm to the flooring or wall, without covering the edge of the flooring, and without relying upon a compression-fit to secure the stanchion in place. Among the many benefits of the present invention includes the ability to affix a life-line to the stanchion. The present system provides superior support as compared to relying upon a compression-fit or other past systems.
Referring now to
In accordance with the invention, stanchion 22 is affixed to wall 520a within bay 530a by utilizing a through-hole 577. The present inventors have discovered that utilizing a through-hole 577 allows for stanchion 22 to be securely affixed to wall 520a in a manner and to a degree that is far superior compared to prior systems. Utilizing through-hole 577 allows stanchion 22 to be affixed without harm to slab 510a or wall 520a, and avoids coverage of or placement about deck edge 515a. Further, utilizing through-hole 577 allows for a positive connection to wall 520a without having to rely upon a compression or friction-fit. Changes to the wall 520a, such as through natural expansion or compression of concrete, for instance, will not affect the secure affixing of stanchion 22 to wall 520. Likewise, changes to stanchion 22, such as through natural expansion or contraction of the material comprising the stanchion will not affect the secure affixing of stanchion 22 to wall 520. Utilizing a through-hole 577 achieves a significant reduction in effort to assemble and/or remove guardrail system 20 and eliminates the need to repair damage to the slab 510a or wall 520a. Utilizing a through-hole 577 also reduces a safety hazard otherwise present with compression or friction-fit systems since natural changes in the structure or materials will not cause stanchion 22 (or system 20) to loosen, dislodge, slip or fall from bay 530a.
In accordance with an advantageous feature of the invention, through-hole 577 is a tie-hole 576 which results from the process of forming wall 520a as generally described above with reference to
A system embodying the principles of the invention can utilize any desired number of through-holes 577. In accordance with an advantageous feature of the invention, system 20 utilizes two through-holes 577. The inventors have discovered stanchion 22 can be affixed using two, or at least two, through-holes 577 without giving rise to a spinning action of stanchion 22 if only one through-hole 577 were otherwise utilized to affix stanchion 22. Utilizing a through-hole 577 at both a lower portion of wall 520 and at an upper or mid portion of wall 520 allows for stanchion 22 to be secured in a generally vertical fashion so that it may support rails 30 as described further below. Use of two through-holes 577 allows for stanchion 22 to be affixed at both a top portion and a bottom portion of stanchion 22, thus resulting in a more secure hold against wall 520a. Use of three through-holes 577 may add additional securing action, however in practice it may be difficult to align three through-holes 577 which would add to the effort of set-up or take-down. Use of two through-holes 577 to affix stanchion 22 to wall 520a is regarded by the present inventors as a preferred embodiment.
In accordance with an advantageous feature of the invention, through-hole 577 is a tie-hole 576. Other through-holes 577, such as a sleeve hole 574, or cone holes or other holes running through wall 520, may also (or alternatively) be used. In accordance with an advantageous feature of the invention, utilizing a through-hole 577 to affix stanchion 22 includes use of a fastener means, which fastener means includes but is not limited to a fastener 24 inserted through the through-hole 577. Fastener 24 may be of any desired variety. In accordance with an advantageous feature, fastener 24 is a threaded pin 24a, such as, for instance, a coil rod that may extend through through-hole 577. Fastener 24 may be made of metal (preferably steel) or other desired material, and may include features similar to coil rods or ties used for setting the panels 553 of forming systems 550.
As shown in
In accordance with an advantageous feature of the invention, stanchion 20 is an elongated member and includes at least two openings or slots 26 (See for instance,
Stanchion 22 is adapted to receive a guardrail, such as a guardrail 30 or safety line or cable 579 (see
As shown in
With further reference to
With further reference to
An anchorage 240 as shown in
As shown in
As shown in
In some non-limiting applications, a fastener 24 or coil rod may have a diameter of about ¾ or ⅞ inches (which is a common English measure for receiving a nut 25 of the Outinord variety used to secure the wall forming panels and ties). As such, distance “d” of channel 55 would then have a measure of at least the same in certain applications. Openings 26c and elongated slots 26d would also have dimensions sufficient to accommodate insertion of such a fastener. The distance “d” separating segments 52, 54 (as well as the dimension of openings or slots 26) may be varied depending upon the type of fastener 24 and/or nut 25 to be used, and vice-versa.
As a further optional arrangement, nut 65b can instead be loose or not welded to cap 60 (or cap 60 can be eliminated in an appropriate case). A worker can simply turn a loose nut 65b upon fastener 24 and then place fastener 24 into opening or slot 26 of stanchion 22 and then through through-hole 576 (or place fastener 24 into through-hole 576 and then place stanchion 22 over fastener 24 and then thread nut 65b. Nut 65b fits within channel 55. Nut 65b is dimensioned to abut or wedge against side segments 52, 54 so that nut 65 does not turn when fastener 24 is turned. In this manner the turning of fastener 24 may further tighten (or loosen) nut 65b against back segment 50. Alternatively, and while not necessarily preferred due to difficulty in aligning opening 26 with a corresponding through-hole 576, nut 65b may be welded to back segment 50.
In further aspects it may be appreciated that stanchion may be made of wood. For instance, stanchion 22 may include a 4×4 (i.e., having a generally 4 inch by 4 inch cross-section) wooden piece. The actual dimensions of a cut 4×4 are often less than exactly 4 inches by 4 inches. Stanchions having other dimensions are also workable. The 4×4 may be secured to the wall structure by passing a fastener 24 through the piece and securing as described above. The 4×4 piece may also include a notch or notches to accommodate fastening with fastener 24 and/or to accommodate tie-off of a life line. For instance, a user may “tie-off” to clip himself directly to fastener 24 that runs through piece 22. A “life-line” may clip onto fastener 24, stanchion 22, a nut or other component of guardrail system 20. Fastener 24 may in part be exposed at a notched location of wooden piece stanchion 22. In further aspects it may be appreciated that stanchion 22 may also be made of or with plastic, including hardened plastic, and treated with hardeners, sealants, UV protections, paint or other treatments. In addition to or instead of use of a metal cable as a guardrail 30, such as use of ⅜ inch or other diameter cable, guardrail 30 may include a strap such as a nylon strap. A ratchet mechanism may be used to wind the strap (or cable) and tighten the same to provide a secure guarding device within the bay of the structure.
In further aspects it may be appreciated that stanchion may be used in conjunction with safety “gates”. Particularly, a “gate” may be constructed to engage with stanchions to secure a bay. The gate operates as a guardrail that spans the bay. Gates are commonly used on construction projects as is known in the art. After work is completed on a bay, the gate may be moved to another bay location (typically upward on the structure) and secured to stanchions, such as stanchions 22 positioned at a different floor or level of the building under construction. The stanchions and gate may be configured such that the gate may be conveniently lifted from the stanchion for efficient yet controlled detachment. Such gates may be “flown” from one bay to another bay by connecting the gate to a crane and lifting the gate upward to the level where an open bay is present. Stanchions 22 are in place for swift connection of a gate within the bay. The stanchions 22 located in the prior bay may then be moved to another bay location for re-use. Re-use of stanchions 22 saves cost and time and reduces waste. The gates and stanchions may be re-used numerous times on a construction project. Utilizing the stanchions 22 under the present invention allows for swift set-up and take-down as compared to prior methods. Additionally, use of stanchions 22 as described above eliminates the need to repair portions of the concrete that would otherwise include nail holes or other alterations made to the concrete structure.
It will thus be appreciated that those skilled in the art will be able to devise numerous alternative arrangements that, while not shown or described herein, embody the principles of the invention and thus are within its spirit and scope.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2011/060523 | 11/14/2011 | WO | 00 | 9/3/2014 |