Device for securing rope ladder steps

This invention is directed to a device for securing a step of a rope ladder to the rope. The device includes an upper and a lower wedge collar, each of which has a central slot through which the ropes to be secured are threaded. The device further includes a diamond-shaped wedge heart which is inserted in the slot between the ropes such that the ropes are compressed between the sides of the wedge collars and the edges of the wedge heart. The wedge heart also has locking lugs on each edge, each locking lug contacting a surface of the upper and the lower wedge collar to prevent the wedge heart from being pulled through the slot in the wedge collars when pressure is applied to the ropes.

FIELD OF THE INVENTION

The present invention relates to rope ladders. More specifically, it relates to a device and method of securing steps to the ropes of rope ladders such that the steps have superior resistance to rope slippage.

BACKGROUND OF THE INVENTION

The following is provided as background only; nothing in this section is intended to be, nor should any of it be construed as, prior art to the present invention.

Rope ladders have many uses. For example, they serve as emergency escape means from buildings and other structures. They also are used as boarding and disembarking means for ships at sea, in particular by local pilots who board ships coming into harbor to assume responsibility for docking them. To reduce any contribution of the rope ladders themselves to the substantial risks involved when using them to embark or disembark a ship, the Coast Guard has mandated rigid specifications to which marine-use rope ladders must adhere. To this end, a number of patents have been issued relating to rope ladders, in particular to the steps of the ladders and to the means by which the steps are secured to the ropes.

One of the earliest patents relating to rope ladders as modernly conceived is U.S. Pat. No. 4,177,878, to Salvarezza, filed 14 Aug. 1978, issued 11 Dec. 1979. Originally, the steps used for rope ladders were made of wood and were susceptible to warping, breakage and general structural non-uniformity. The advent of superior strength polymers led to the development and use of steps made of hard, tough, durable polymeric materials. Thus, U.S. Pat. No. 4,241,809 to Salvarezza, filed 13 Aug. 1979 and issued Dec. 30, 1980, also to Salvarezza, is directed to a rope ladder with a molded hard elastomer step and a method for assembling ladders using such steps. Another patent, U.S. Pat. No. 4,554,996, likewise to Salvarezza, filed 12 Apr. 1985, issued 26 Nov. 1985, is directed to additional features of molded hard elastomer rope ladder steps as well as to replacement steps and collars. U.S. Pat. No. 4,655,321, again to Salvarezza, filed 29 Aug. 1986 and Issued Apr. 7, 1987, adds to the art an improved method for assembling rope ladders comprising molded hard elastomer steps and U.S. Pat. No. 4,683,981, to Salvarezza, is directed to molded hard elastomer steps having additional features, to replacement and spreader steps and to novel methods of molding the steps. Each of the preceding patents is incorporated by reference, including all drawings, as if fully set forth herein.

While the means for securing the steps to ropes in the above patents surpass all Coast Guard specifications with regard to load-bearing without rope slippage, even greater non-slippage capability, and therefore an even greater margin of safety, is always desirable. The present invention provides a means for securing ropes to the steps of rope ladders that renders the likelihood of slippage of the steps along the rope vanishingly small under virtually any load.

SUMMARY OF THE INVENTION

Thus, in one aspect, the present invention relates to a device for securing ropes to steps of a rope ladder, comprising:a upper wedge-collar comprising:a top surface having a length and a width;a bottom surface substantially parallel to the top surface, having a length and a width substantially the same as the top surface, the top surface being coupled to the bottom surface by an edge surface;an elongate slot extending through the upper wedge-collar from the top surface to the bottom surface, the slot being defined by two side-walls and two end walls, wherein:the side walls and end walls are perpendicular to the top and bottom surfaces;the side walls are substantially straight;the end walls are curved, wherein the curve may be simple or complex;at least two fastener bores extending through the wedge-collar from the top surface to the bottom surface;at least two fastener bore extensions, one for each fastener bore, coupled to the bottom surface such that a lumen through each extension aligns with each fastener bore;a lower wedge-collar comprising:a top surface having a length and a width;a bottom surface substantially parallel to the top surface having a length and width substantially the same as the top surface, the top surface being coupled to the bottom surface by an edge surface;an elongate slot extending through the lower wedge-collar from the top surface to the bottom surface, the slot being defined by two sidewalls and two end-walls, wherein:the side walls are perpendicular to the top and bottom surfaces;the end-walls are rounded and inwardly tapered from the top surface to the bottom surface such that the slot is larger at the top surface than it is at the bottom surface; and,a wedge-heart comprising:a diamond-shaped first surface having an upper vertex, a lower vertex and two transverse vertices; and,a diamond-shaped second surface parallel to the first surface, the second surface being of substantially the same size and shape as the first surface and likewise having an upper vertex, a lower vertex and two transverse vertices, wherein:the second surface is coupled to the first surface by a concave edge surface comprising a first edge-rim and a second edge-rim, each of which extends the entire perimeter of the edge surface, wherein:each edge-rim comprises two locking lugs, one located substantially at each transverse vertex, wherein:the upper wedge-collar, the wedge-heart and the lower wedge collar are operationally coupled to one another.

In an aspect of this invention, the end-walls of the lower wedge-collar comprise raised ribs substantially parallel to the top and bottom surfaces.

In an aspect of this invention, the edge-surface of the wedge-heart comprises raised ribs substantially perpendicular to the first and second surfaces of the wedge-heart.

In an aspect of this invention, the end-walls of the lower wedge-collar comprise raised ribs substantially parallel to the top and bottom surfaces and the edge-surface of the wedge-heart comprises raised ribs substantially perpendicular to the first and second surfaces of the wedge-heart.

In an aspect of this invention, the upper wedge-collar, the lower wedge-collar and the wedge-heart are separate units.

In an aspect of this invention, the upper wedge-collar, the lower wedge-collar and the wedge-heart each comprise a polymer, which may be the same as, or different from, the polymer of each of the others.

In an aspect of this invention, the upper wedge-collar, the lower wedge-collar and the wedge-heart comprise the same polymer.

In an aspect of this invention, polymer comprises a hard, tough moldable polymer.

In an aspect of this invention, the polymer is nylon.

In an aspect of this invention, the upper wedge collar is an integral part of a molded polymeric step and the lower surface of the upper wedge-collar and the fastener bore extensions do not exist.

An aspect of this invention is a rope ladder step comprising the device of claim1.

An aspect of this invention is a rope ladder comprising a plurality of the rope ladder steps of claim11.

DISCUSSION

As used herein, the term “substantially” means that, to one skilled in the art, the feature so-modified is, in its structurally important features, as described. Thus, for example, when it is stated that a side wall is “substantially” straight, what is meant is that the wall may have some small degree of curvature but, to one skilled in the art observing the wall in view of the claims and the function of the wall, would see the wall could be described as straight. Likewise, “substantially parallel” surfaces may have features that protrude from the surfaces but, to one skilled in the art, it would be apparent that the surfaces are, in a structural sense, parallel.

As used herein, the term “simple curve” means a curved feature having a single radius of curvature and a “complex curve” means a curved surface having two or more radii of curvature.

FIG. 1shows a schematic representation of a portion of a rope ladder of this invention. Two sets of ropes1and2and3and4are disposed at either end of steps10. The ropes are secured to the steps by means of upper wedge collars20, lower wedge collars30and wedge-hearts40. It is, of course, understood that the three steps shown inFIG. 1are for illustrative purposes only and that an actual rope ladder would consist of many more such steps, each of which is secured to the ropes in the same manner.

FIG. 2is a schematic representation of upper wedge-collars20. Upper wedge-collars20are made of a hard, tough resilient material such as, without limitation, wood, metal or plastic. Hard, tough, resilient moldable polymers such as nylon are presently preferred. Upper wedge-collars20have fastener bores22at either end through which fastening means such as, without limitation, screws, rivets or, in a presently preferred embodiment of this invention, bolts, are inserted to secure upper wedge-collars20and lower wedge collars30to steps10as shown inFIG. 6. In addition, upper wedge collars20have a slot23through which the ropes of the rope ladder pass. Another feature of upper wedge-collars20is fastener bore extensions25. Extensions25are made of non-conductive material, preferably the same hard polymeric material as the rest of upper wedge-collars20so that extensions25can be molded as integral parts of the upper wedge collars. Extensions25pass through holes13(FIG. 6) in the steps so that, if the portion of the step through which a fastening means will extend is made of metal, as in the case, without limitation of a step constructed of a metal frame to which a polymeric step surface has been molded, the metal of the hole in the step that aligns with the fastener bores in the wedge-collars will not contact the fasteners, which preferably are made of metal such as, without limitation, stainless steel, when they are inserted into the fastener bore. In this manner, electrolysis resulting from metal on dissimilar metal contact and the attendant corrosion of the step and/or the fastener, in particular under the influence of salt water in a marine-use environment, is avoided.

FIG. 3is a schematic of lower wedge-collars30. Lower wedge-collars30are also made of a hard, tough resilient material such as, without limitation, wood, metal or plastic. Hard, tough, resilient moldable polymers such as nylon are presently preferred. Lower wedge-collars30also comprise two fastener bores31at either end. When a step is assembled, fastener bores22align with fastener bores31(and the corresponding holes in the step,FIG. 6) so that a fastener can be passed through all three elements, upper wedge-collar20, step10and lower wedge-collar30. Lower wedge-collar30also comprises a slot32, which has substantially straight, vertical side-walls33and tapered, curved end walls34. In use, top surface35of lower wedge-collar30is in contact with underside surface15of step10such that, due to the taper in the end-wall surfaces, slot31is larger at the point of contact of the wedge-collar with the step than it is at bottom surface36of lower-wedge-collar30, which surface is furthest from underside surface15of the step. Curved surface34of lower wedge-collar30optionally also has generally horizontal (i.e., substantially parallel to the top and bottom surfaces35and36) raised protrusions or ribs37, which serve to increase the frictional force on ropes passed through slot32when a step is being secured to the ropes.

FIG. 4is a schematic representation of wedge-heart40. Wedge-heart40is also are made of a hard, tough resilient material such as, without limitation, wood, metal or plastic. Hard, tough, resilient moldable polymers such as nylon are presently preferred. Wedge-heart40comprises two parallel, generally diamond-shaped surfaces58and59, each having an upper long apex41and a lower long apex42and transverse short apices43and44. Wedge-heart40also has a concave edge surface45that serves as a rope guide when the wedge-heart is in use, The concave edge surface or rope guide extends the entire perimeter of wedge-heart40and comprises edge-rims46and47that likewise extend the entire perimeter of wedge-heart40. Groove/concave edge surface/rope guide45may be smooth or textured. In a presently preferred embodiment, rope guide45has substantially horizontal (i.e., perpendicular to the first and second surfaces,58and59) raised protrusions or ribs48along its entire length. The number of ribs shown inFIG. 4is illustrative only and is not intended to depict the number of such ribs on an actual wedge-heart nor is it intended, or is it to be construed, to limit the scope of this invention in any manner whatsoever.

Edge rims46comprises locking lugs51and52, the lugs being located substantially at transverse apices43and44. Likewise, edge rim47comprises locking lugs49and50, the lugs likewise being located substantially at transverse apices43and44. By substantially is meant that the lugs, whatever their shape, need not be centered on the apices, what is required is that the distance from the outermost lug surface55of locking lug49, that is, the surface that will be closest to the bottom surface of upper wedge-collar20in a properly assembled step, to the outermost edge of lug surface55of locking lug51and the distance from the outermost edge of lug surface55or locking lug50to the outermost edge of lug surface55of locking lug52are such that, when wedge-heart40is inserted through slot21of upper wedge-collar20, each locking lug will contact lower surface26of upper wedge-collar20thus preventing the wedge-heart from passing completely through the slot in the upper wedge-collar. Such is most conveniently accomplished when the lugs are at the transverse apices of the diamond-shaped wedge-heart and also, when so located, the lugs have optimal strength compared to lugs situated otherwise wherein the surfaces55would have to be longer, and therefore weaker, to contact the upper wedge-collar bottom surface. Furthermore, while the locking lugs as shown inFIG. 4are generally rectangular in shape, any suitable shape, many of which will become apparent to those skilled in the art based on the disclosure herein, may be used. All such shapes are within the scope of this invention.

Steps10can be constructed in numerous ways. For example, without limitation, they may be unitary molded polymeric constructs with appropriate slots and fastener holes that align with the slots and fastener bores in the upper and lower wedge collars. In fact, if desired, the upper wedge-collar may be molded with the rest of the step so that they form an integral unit. Alternatively, again without limitation, a step may consist of a rectangular metal frame with longitudinal members that generally describe the length of the step and cross-members that generally describe the width of the step, the cross-members being perpendicular to, and disposed at opposite ends of, the longitudinal members. The cross-members may be strengthened by additional cross-members disposed along the length of the longitudinal member or by diagonal members attached at one end to a longitudinal member and at the other end to a cross-member. In this construct, the end cross-members have slots and fastener holes that align with the wedge-collar slots and fastener extensions. A polymeric step piece is then molded around the frame. Other step constructs will likewise become apparent to those skilled in the art based on the disclosure herein; all such constructs are within the scope of this invention.

In a presently preferred embodiment of this invention steps10comprise longitudinal scaffold members11and12(FIG. 6) which can be made of any strong, durable break-resistant material but are typically metals such as steel, aluminum, iron and the like. Scaffold members11and12are entirely separate constructs that will eventually be held together by fasteners extending through the fastener bores of the upper and lower wedge collars and holes13in the scaffold members. The cross-sectional shape of the scaffold members may be any that confers sufficient strength on the members. Many such shapes are known to those skilled in the art; all are within the scope of this invention. Generally, a square or rectangular cross-section shape is used. The scaffold members can be solid or they can consist of an outer surface and an inner surface that describes a lumen, such as lumen14inFIG. 6, that runs the length of the member. This construct is presently preferred in order to render the finished rope ladder, which may consist of a large number of steps, as light as possible.

To assemble a rope ladder of this invention two pairs of two ropes, e.g., ropes1and2ofFIGS. 1 and 5are passed through slot32of lower wedge-collar30, through slot23of upper-wedge collar20(the discussion that follows is directed to one end of a rope ladder step. It is understood that the same operations will be performed at the other end of the step with ropes3and4). Fastener extensions25are inserted through holes13in scaffold members11and12. A wedge-heart40is inserted between ropes1and2such that upper vertex41passes through slot23of upper wedge-collar20and lies a short distance above the plane of top surface27of upper wedge-collar20and lower apex42is inserted into slot31of lower wedge-collar30such that the apex extends a short distance beyond the plane of lower surface36of lower wedge-collar30. Ropes1and2are set in concave rope-guide45on either side of wedge-heart40as shown inFIG. 5. Threaded bolts (not shown) are inserted through fastener bores22of upper wedge-collar20, through fastener extensions25, through holes13(FIG. 6) of scaffold members11and12and through fastener bores31of lower wedge-collar30. Nuts are screwed onto the bolts and tightened. As the nuts are tightened, ropes1and2are compressed and frictionally secured between tapered, curved ribbed surface34of lower wedge-collar30, ribbed rope guide45of wedge heart40and the smooth or ribbed surface of upper wedge-collar20as shown inFIG. 5. As a result of the tightening, locking lugs49and,50are brought in contact with bottom surface26of upper wedge-collar20. When properly assembled with the correct size rope, that is rope having a diameter larger than the diameter of the opening created by rope guide45and tapered, ribbed surface34of lower wedge-collar30as well as the opening created by groove45and the vertical curved surface of upper wedge-collar20so that the rope is compressed in the openings when the step is fully assembled, the rope is held firmly and cannot slip. Even if a tremendous amount of downward pressure, which otherwise might be sufficient to cause wedge-heart40to slip through slot23of upper wedge-collar20, is applied, locking lugs49and50will prevent such from occurring. It is in fact believed that the rope-securing device of this invention may be sufficiently slip-resistant that pressure on a step would be sufficient to cause the step to buckle and break before slippage of any of the ropes occurred.

Based on the disclosures herein those skilled in the art will recognize many changes that might be incorporated in the construction of the rope-securing device of this invention as well as widely different embodiments and applications thereof. All such changes, embodiments and applications are within the scope of this invention.