Various embodiments relate generally to variable-height attachment point assemblies for cooperative use with safety harnesses and the like.
Safety harnesses are widely used by persons working on elevated structures to catch the person in the event of a fall. Workers can be seriously injured or killed from falls, which may be the result of being struck by moving machinery or structural members, or simply losing their balance. In some cases, construction workers may wear a safety harness that includes a tether that can be attached to a stable structural member, such as an I-beam or a joist when they are working at elevated heights. Thus, if a worker does fall, their descent may be generally limited to the length of the tether.
Systems and methods relate to an operator selectable, variable-height attachment point system for a safety harness, where the attachment point is disposed on a radial support member that can be reversibly coupled to a vertical support member, and where the attachment point height can be selected by the operator by reversing a coupled orientation of the radial support member to the vertical support member.
In an exemplary embodiment, a variable-height attachment point system for a safety harness may include an elongate vertical support member configured to receive and reversibly couple to an elongate radial support member. The radial support member may extend, for example, substantially radially from an end section of the vertical support member. In some examples, the radial support member may include bends at each end section where the bend angles are different from each other. The unequal bends in the radial support member may allow, for example, the orientation of the radial support member relative to the vertical support member to be selected by an operator. Each end section of the radial support member may include an attachment point for a safety harness, such as an aperture configured to receive a safety harness tether or a similar article, for example. In various embodiments, an operator may position a safety harness attachment point at a desired height from a working surface by selection of which end of the radial support member to couple to the vertical support member.
In accordance with another exemplary embodiment, a variable-height attachment point system for a safety harness includes a base configured to receive the elongate vertical support member. In certain embodiments, the base can be a cage-like structure capable of stabilizing the vertical support member in different ways. For example, in one embodiment, the base can be configured for receiving counterweights that provide structural stability of the attachment point system. In another embodiment, the base can be configured so that a portion of the base can receive the weight of a vehicle tire. In yet another embodiment, the base can be configured to be sunken into malleable cement so as to provide a stable footing into which an end portion of the vertical member can be inserted.
In various embodiments, the components of a variable-height attachment point system can be modular, providing the capability to build the system to a preferred working height above a surface.
In accordance with another exemplary embodiment, a variable-height attachment point system for a safety harness may include a radial support member capable of absorbing unintended forces imparted to the system so as to protect a person tethered thereto, and the system itself. For example, in one embodiment, a radial support member can include a breakaway hinge configured to hingedly give way to an unintended force applied to a distal end portion of the radial support member. Such unintended forces can result from, for example, moving machinery, falling debris, or structural members of a building being moved by other machinery.
Various embodiments may achieve one or more advantages. For example, some embodiments may allow a user to easily select between at least two attachment point heights for connecting a tether of a safety harness. In some implementations, variable height selection of the attachment point may be accomplished with a minimum number of components. Various embodiments can be useful, for example, when a user is working above a surface at multiple heights. Another advantage of some embodiments may include the ability to lift a fall-arresting system of the type described herein using a common (e.g., low load capacity, light duty) forklift. Yet another advantage includes the relatively lightweight nature of the system components, which can allow a user to select between at least two attachment point heights without requiring lifting machinery to do so.
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, one embodiment of a variable-height attachment point system for a safety harness is briefly introduced with reference to
In this embodiment, the system 100 includes a base 105 configured to securely receive an end section of an elongate vertical support member 115. The base 105 can be a portable cage structure that provides structural support for the system 100 in a substantially upright and operable configuration as generally depicted in
In this embodiment, the elongate, vertical support member 115 includes a second end section 117 configured to securely receive a radial support member 120. The vertical support member 115 can be formed as a single material piece, or, in some embodiments, can be formed from a plurality of structural members as described in greater detail below, specifically with respect to
In the depicted embodiment, the radial support member 120 includes two oppositely-disposed end sections as described in greater detail below, each of which is configured to be securely inserted into the second end section 117 of the vertical support member 115. Each of the end sections of the radial support member 120 provides an attachment point for a tether 125 of a safety harness assembly. Furthermore, each of the end sections of the radial support member 120 includes bends near to the terminal end at each side. In this embodiment, the bends are formed at different angles from each other; accordingly, the radial support member 120 can be oriented at different angles with respect to the vertical support member 115, depending on which end section of the radial support member is inserted into the second end section 117 of the vertical support member.
Still referring to
Referring now to
The first end 116 of the vertical support member 115 is configured to be inserted into the base 105 as previously described. In this embodiment, the first end 116 is tapered so as to fit in a complementary receptacle in the base 105. Attachment of the vertical support member 115 to the base 105 can be accomplished using various fastening members, including, but not limited to bolts, screws, nails, dowels, and the like. In one embodiment, the base 105 includes a cylindrically-shaped receptacle configured to receive substantially all of the first end section 116.
The second end 117 of the elongate vertical support member 115 is configured to receive an end section of the radial support member 120 as previously described. In this embodiment, the radial support member 120 includes first and second oppositely-situated end sections 121, 122, respectively, spanned by an elongate central member 123 that is substantially coplanar with the end section 121, 122, and defines a radial axis. In this embodiment, each of the end sections 121, 122, includes a bend in the central member 123 at first and second bend angles θ1 and θ2 respectively, where θ1≠θ2. For example, either of the end sections 121, 122 can be bent at an angle between about 80° and about 150°, e.g., about 80, 90, 100, 110, 120, 130, 140, or 150 degrees. In some examples, one of the angles may be acute, and the other may be obtuse, to provide a substantial height differential at the attachment point, depending on which of the end sections 121, 122 is coupled to the vertical support member 115.
In this embodiment, each of the end sections 121, 122, is configured to provide an attachment point for a tether member of a safety harness system. In this embodiment, the attachment point in each end section 121, 122 is an aperture, e.g., aperture 124, through which a user can tie, or otherwise anchor the tether portion of a safety harness. It will be understood that end section 121 in
In this embodiment, the radial support member 120 further includes a connector member 127, 128 respectively, on each end section 121, 122. Here, the connector members 127, 128 are U-shaped members integral with, or securely fastened to the central member 123 that provides a lifting point for the vertical support member 115 and radial support member 120 when in a coupled configuration. In this embodiment, the position of the connector members 127, 128 may be disposed at or substantially near a center of gravity of the vertical support member 115 and radial support member 120 combination, when coupled in an operable configuration, e.g., as illustrated in
In this embodiment, the second end 117 of the vertical support member 115 includes a U-shaped notch, referred to by reference number 119, which is defined in part by opposing wall members 119a, 119b of the central member 118 as shown. In this embodiment, each of the wall members 119a, 119b includes an aperture 130 configured to receive a fastening member such as a bolt, cotter pin, dowel, or similar member capable of passing through the central member 118 and the aperture of either end section 121, 122 of the radial support member 120, e.g., aperture 124.
Referring to
Referring now to
In this embodiment, a guy 140 is coupled to the second end section 117 of the vertical support member 115 at one end, and coupled to the connector member (in this case connector member 128) at the free (non-inserted) end 122 of the radial support member 120. The guy 140 can be connected to either coupling point using bolts, dowels, pins, or other types of fastening mechanisms known in the art. In this example, the guy 140 is coupled to connector member 128 using a carabineer 145, which is one of many coupling options. The guy 140 can provide additional stability for the system 100; for example, the guy 140 can increase resistance to moment forces at the inserted end of the radial support arm 120 (e.g., end 121) when downward forces are applied at the free end, e.g., end section 122 as illustrated in
The capability of the system 100 to provide a variable-height attachment point for a safety harness tether member is exemplified in
Referring now to
Referring now to
In this embodiment, the second end 117 of the vertical support member 115 is configured to receive either end section of the radial support member 120, however, the U-shaped notch depicted in, e.g.,
Referring now to
Referring now to
Referring now to
Referring now to
In the
In another exemplary embodiment, a base 519 includes a first arm 521 and a second arm 523 that bisects the first arm 521, and includes cross-braces, e.g., cross braces 527, 529 to form a rigid cage structure as illustrated. In this embodiment, a centrally-disposed plate 525 is configured with bolt holes, which can be threaded bolt holes in some embodiments, so as to match the bolt hold pattern in the first segment 562. In this embodiment, stability of the system 500 can be increased by applying sandbags or other counterweights around the cage structure.
In the
In one exemplary embodiment, the wheel plate can be substantially flat, i.e., absent the platform 567, so that the base 560 can be shifted between folded and unfolded configurations while the wheel plate 565 remains attached. In such an embodiment, the wheel plate can be attached, e.g., to the second arm 563a. In this embodiment, a centrally-disposed plate 571 includes bolt hole patterns as previously described to accommodate secure attachment of the first segment 162 to the base 560.
In this and other exemplary embodiments, the base 105 may be portable. For example, the base 105 can include one or more castor assemblies securely attached to one or more of the arms 507, 509, 521, 523 or the cross-braces 511, 513, 527, 529 so as to make the system 100 portable. For example, a user can roll the assembled system 100 to chosen locations by virtue of the castors.
Referring now to
Referring now to
In this embodiment, the radial support arm 720 is formed of first 727 and second 729 sections hingedly coupled by a breakaway hinge 725. In this embodiment, the second section 729 of the radial support arm 720 can collapse, e.g., shift from the first orientation (solid line in
In various embodiments, the breakaway hinge 725 can be a hinge that allows the second section 729 to hingedly shift from a first orientation to a second orientation when a threshold force is applied to the support arm 720, specifically, to a distal end section 750 of the radial support arm 720. In one embodiment, a shear pin configured to break at a certain threshold shear force can be utilized. In this embodiment, the distal end section 750 of the radial support arm includes an aperture 751 that serves as a connection point for a tether of a fall-arresting safety harness.
In this embodiment, the system 700 further includes a guy spanning from a first end section 716 of the vertical support member to a distal section of the first section 727 of the radial support member 720 proximal to the breakaway hinge 725 for supporting the first section 727 in an operable configuration, e.g., the configuration shown in
Although not depicted in
Referring now to
In this embodiment, a distal end of the radial support arm 820 includes two U-shaped bolts 825, 827, each having two threaded arms protruding from a U-shaped base. The threaded arms extend through the cross-section of the radial support arm 820 and protrude on an opposite side of the U-shaped base to provide attachment points for a proximal attachment ring assembly 825a, and a distal attachment ring assembly 827a, as shown. In this embodiment, a reversibly-securable linking assembly 842 can conjoin the loop 841 to either the proximal (825a) or distal (827a) attachment ring. Exemplary linking assemblies 842 include, not by way of limitation, carabineers, quick-links, and other resilient linking mechanisms. It will be understood in this and other embodiments that while
Referring now to
Referring back to
In some cases, it may be beneficial to utilize a U-shaped clamp 830 having a self-locking pin assembly that automatically snaps into locking engagement with locking apertures disposed on the top portion 865 of the vertical support member 815, in case the locking apertures are out of reach of the user. In one such example, a locking pin 834a can be engaged with the U-shaped clamp by one or more spring mechanisms. The spring mechanisms can provide constant urging force for the pin 834a to shift toward the opposite side of the U-shaped clamp, so that when the U-shaped clamp is positioned correctly at the top portion 865 of the vertical support member 815, the springs urge the pin through the vertical support member so as to protrude from the opposite side of the U-shaped clamp 830.
Referring now to
The adapter 880 can be used alone or with other components to attach the vertical support member 815 to any suitable base, including the pillar 886 as illustrated In this embodiment, a ring-shaped void is defined by the space between the outer circumference of the adapter 880 and the inner circumference of the stabilizing receptacle 888 which can receive the vertical support member 815. In this embodiment, the second end 883 of the adapter 880 includes a pair of oppositely-disposed apertures 885 (only one aperture is illustrated in
Although various embodiments have been described with reference to the figures, other embodiments are possible. For example, the various components of the systems described herein, e.g., the vertical or radial support members, including segmented versions thereof, can be formed from suitable materials according to its intended use. Additionally, any feature, component, or description in one embodiment can be applied to another embodiment for the advantages that may be apparent to skilled artisans. The various components of the described systems can be interchangeable. For example, the various bases and footers described herein can receive, or be adapted or configured to receive an end portion (e.g., end portion 116) of a vertical support member 115. In various embodiments, the disclosed footers and bases can include rotational bearings or otherwise provide rotational mobility of the vertical support member so that the radial support member can freely rotate to follow a user as he moves about the work surface.
In one embodiment, a system can include shock absorbers to reduce the likelihood of trauma from arresting forces if a user falls from a work surface.
In various embodiments, the described components can be formed from steel, including tubular steel, e.g., rectangular-tubular, cylindrical-tubular, etc., although other materials can be substituted according to preference or other considerations. The figures are not necessarily drawn to scale. Thus, any component of any system or embodiment described herein can be sized according to user preference according to the intended use of the system or embodiment. The systems described herein can be adapted or configured to cooperate with a specific type of safety harness system not described herein. In some cases, multiple systems and embodiments can be used simultaneously by a plurality of users. While specific reference has been made to the construction and transportation industries, other use of the disclosed systems and methods are equally contemplated in other industries and recreational activities. For example, a system of the type described herein can be used as fall-arrestor for recreational climbing walls.
In various embodiments, apparatus and methods may involve coupling a vertical support member (e.g., vertical support member 115) directly to a stabilizing structure. In a related embodiment, a vehicle such as a fire engine can include a recess configured to receive and secure an end portion of a vertical support member on the side of the engine. Such an embodiment can provide a variable-height attachment point for a safety harness worn by firefighters when operating on top of the engine, e.g., when re-loading hose or ladders.
In various embodiments, the attachment point can be adapted or configured to cooperate with any type of safety harness. For example, the attachment point can be an aperture of any size, as previously described, or the attachment point can include, without limitation, integral connection mechanisms such as clips, hooks, clamps, couplings, keepers, and/or latches, for example.
In various embodiments, the system can include a vertical support member of sufficient height to provide clearance above a worker, and can have an attached radial support member to provide a connection point at an appropriate horizontal distance from the base anchor point. The radial support member can be connected to the vertical support member in such a way as to prevent deflection by means of increased stiffness produced by web, guy line, or structural support members. In some embodiments, the horizontal member and the vertical member can substantially resist deflection under forces that may be imparted to the system during a fall protection scenario. In some cases the anchor point may support up to at least approximately 1800 pounds or more, for example.
In one embodiment, the base of the vertical support member can be reinforced, and can interface with the base by means of an easily rotatable connection point, such that the vertical member can stay completely vertical, and can rotate easily with the force applied to the attachment point by a human. In various embodiments, the base or footer can be 1) a metal cone which can be embedded in concrete; 2) a metal cone mounted to a metal anchor which attaches to a beam by means of, for example, a clamp, bolt; 3) a modular flat base upon which specified weight can be placed and secured, whether in a specified container, or of a specified material of specified weight; and/or 4) a flat base upon which both integral counter-weight and a vehicle of specified weight can be parked to provide a working weight.
Various embodiments may include structures for reversibly coupling first or second end sections of a radial support member to a receptacle at an end section of a vertical support member in a fall protection system as disclosed herein. For example, referring to
Various embodiments may include structures for selectively positioning a safety harness attachment point at an operator selectable height in a fall protection system as described herein. For example, referring to
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.
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Number | Date | Country | |
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20140090927 A1 | Apr 2014 | US |