The disclosure relates generally to a stowable ladder configured for installation in an opening, such as an opening in a ceiling of a house (e.g., attic ladder), an opening in a ceiling of a building floor, or an opening to a suspended storage space (e.g., an elevated garage storage area) to provide temporary access between one floor or space and another floor or space.
Examples of stowable ladders, attic ladders, “disappearing stairways” and the like are shown, for example, in U.S. Pat. Nos. 2,649,237 and 2,852,176. Such ladders normally fold and retract upwardly into a frame secured between adjacent joists of the attic, and the folded ladder is covered by a door or panel which normally extends substantially flush with the finished ceiling of the room in which the ladder is mounted. These ladders are thus configured to take up no floor space except when actually extended and are also inexpensive to construct, as compared with fixed stairways typically constructed on-site.
U.S. Pat. No. 4,281,743 issued to Fuller on Aug. 4, 1981 shows another conventional attic ladder. As shown in
U.S. Pat. No. 4,541,508 issued to Lundh on Sep. 17, 1985 shows yet another conventional attic ladder. In
However, despite the above-noted improvements to the attic ladder and disappearing stairway art, additional improvements can be realized in the structure of the attic ladder.
In one aspect, a foldable ladder configured for installation in an opening to provide access between one floor or space and another floor or space includes an upper ladder section and a lower ladder section, each comprising a left ladder rail and a right ladder rail. A hinge rotatably connects the upper ladder section ladder rails to the lower ladder section ladder rails. A plurality of steps are rotatably disposed between the upper pair of ladder rails and the lower pair of ladder rails and are configured for rotation between a retracted position and a deployed position.
In still another aspect, a stowable ladder includes upper and lower ladder sections, each comprising a left ladder rail and a right ladder rail and each having at least one step disposed therebetween. The lower ladder section is configured to translate and/or rotate with respect to the upper ladder section into a deployed position substantially co-linear with the upper ladder section. At least one of the steps is rotatably disposed and is configured for rotation between a retracted position and a deployed position.
Additional advantages will become readily apparent to those skilled in this art from the following detailed description, wherein only preferred aspects of the present concepts are shown and described. As will be realized, the disclosed concepts are capable of other and different embodiments, and its several details are capable of modifications in various obvious respects, all without departing from the spirit thereof. Accordingly, the drawings and description are to be regarded as illustrative in nature, and not as restrictive.
Reference is made to the attached drawings, wherein elements having the same reference numeral designations represent like elements throughout, and wherein:
a)–11(b) are, respectively, a side view and a front view of an example of folding ladder and support frame in a fully open position in accord with the present concepts;
a)–12(b) are, respectively, a side view and a front view of an example of folding ladder and support frame in a fully open position with steps in a partially open (45°) position in accord with the present concepts;
a)–14(b) are, respectively, a front view and a side view of an example of folding ladder and support frame in a fully open position with steps in a fully open position in accord with the present concepts;
With reference to the attached drawings, there is described a folding or stowable ladder configured for installation in an opening, such as an opening in a ceiling of a house (e.g., attic ladder), an opening in a ceiling of a building floor, or an opening to a suspended storage space (e.g., an elevated garage storage area) to provide temporary access between one floor or space and another floor or space.
b) show an example of folding ladder 100 and support frame 200 in accord with the present concepts wherein the ladder sections comprising an upper section 110, middle sections 120 and lower sections 130, 140 are shown in various positions as the folding ladder is unfolded from the support frame. It is to be understood that the concepts expressed herein apply equally to a folding ladder bearing any number of folding sections, including but not limited to two, three, four or more.
Support frame 200 is configured for installation within an opening, as described more fully herein, such as but not limited to openings in a ceiling of a house (e.g., attic ladder), openings in a ceiling of a building floor, or openings to a suspended storage space (e.g., an elevated garage storage area) to provide access between one floor or space and another floor or space. Upper ladder section 110 is secured to an upper side of panel 300 by one or more conventional brackets 301 (see
Panel 300 is adapted to rotate relative to support frame 200 and may alternatively be hingedly connected by a conventional hinge arrangement 201 to the support frame, as shown, and/or may simply be connected to the ladder 100, which is configured to rotate with respect to the support frame. In one aspect, the panel 300 is configured to substantially occlude the aforementioned opening when the ladder is in a folded and stowed position (e.g., a 0° angle α between the panel 300 and the support frame 200). Panel 300 may be configured to blend in with the surroundings (e.g., to blend in with a ceiling) for aesthetic reasons. Alternatively, panel 300 may advantageously be configured by way of color, shape, and/or size in distinction to the surroundings so as to draw attention thereto (e.g., fire escape pathway/emergency access panel).
Folding ladder 100 may optionally include an adjustable foot 500, an example of which is shown in
Rotation of each ladder section relative to an adjoining section is accomplished by means of a hinge 400, which is broadly defined herein to include any means by which rotation of one element may be had relative to another element and includes, but is not limited to a pin. In one aspect, hinge 400 may optionally comprise a locking hinge and such hinge could be separately provided for each of the paired upper and lower ladder rails (e.g., 110, 120 or 120, 130) or may traverse the width of the ladder, spanning the distance between the left ladder rails 105 and the right ladder rails 106. Each locking hinge 400 could be configured, in a manner known to those or ordinary skill in the art, to lock at one or more predetermined angles β between adjoining ladder sections. For example, hinges 400 could be configured to lock one ladder section (e.g., upper ladder section 110) and another ladder section (e.g., middle ladder section 120) at an angle of 180° (i.e., ladder sections 110, 120 are parallel and co-linear as shown, for example, in
Hinges 400 may optionally be configured to lock at additional predetermined angles β (e.g., 90°) between adjoining ladder sections to provide, for example, protection against unintentional rapid deployment of the folding ladder. As further protection against unintentional rapid deployment of the folding ladder, the strut itself may be configured to function as a braking mechanism in the opening direction. In another aspect, hinges 400 may advantageously comprise a resistance mechanism to provide increased resistance to opening or closing at various rotational points, in lieu of or in combination with a locking mechanism. A resistance provided by the resistance mechanism could be overcome by application of predetermined levels of force from a user desiring to unfold or fold the folding ladder. One example of a resistance member could include slight protuberances aligned to contact each other or a slight protuberance (e.g., a spring loaded pin) and corresponding recess aligned to mate with each other at one or more specific predetermined angles β between adjoining ladder sections, such that an increased force, above that required to effect the remainder of the relative rotation between the ladder sections, is required to overcome the increased resistance provided by the resistance member at the predetermined angles. The optional resistance members may therefore improve control and stability of the folding ladder 100 during opening and closing operations.
A common feature of all current attic ladders is the use of stationary or fixed steps, as shown in
The steps 150 thereby provide, in a final position, stable horizontal or substantially horizontal surfaces which may be used to safely ascend or descend the ladder 100. In accord with the concepts expressed herein and the uses to which ladder 100 may be placed, the term substantially horizontal is used as a broad term including any attitude of the step which may feasibly be used for safe ascent or descent of the ladder, which can be influenced by the surface of the step (i.e., high coefficient of friction treatments or surface), and could include steps angled at up to about 20°, although an angle of 5° or less or even 2° or less is preferred.
b) shows a front view of one concept of a folding ladder 100 in a fully open position, wherein the rotatable steps 150 are in a retracted or fully closed position, whereas steps 155 are fixed in position.
In the example of the folding ladder shown in front view
As shown more clearly in
Alternate configurations of rotatable steps employing conventional rotational connections are also considered within the scope of the present concepts including, but not limited to, pivot joints provided at the connection between the steps and the rails. Additionally, in lieu of the aforementioned configuration wherein a rear portion of each of the steps 150 is rotatably connected to the ladder rails (e.g., 105, 106) via a step bar 151 to permit unfolding of the step in an upward or downward respect, as desired, the step bar or other conventional rotational connection may be provided at the front portion of each of the steps. Still further, the step rail 160 need not necessarily be jointed for folding. The step rails 160 could simply comprise a straight member, such as a rod, bar, or slat, connected to each of the steps in a corresponding ladder section (e.g., upper ladder section 110) via a rotatable joint (e.g., a pin secured against lateral movement). Step rails 160 may be omitted or may optionally be provided for one or more ladder sections.
Step rails 160 may optionally be configured to ride on top of ladder rails 105, 106, comprising for example, a substantially planar or a U-shaped configuration adapted to mate with or abut against a front surface 107 of each ladder rail 105, 106 and link member 175 could be adapted to rotatably connect thereto, such as by a pin. In one aspect, the step sections corresponding to the ladder upper section 110 and middle section 120 (and lower section 140, if applicable) could be separated by elimination of a joint (i.e., 165) joining the step rails 160, so that the steps 150 may be operated in a discrete grouping corresponding to the ladder section. Such configuration would permit a slightly wider step 105, while retaining a minimized stack height, even though not all steps 150 could be simultaneously opened or closed a user would be required to separately deploy each set of steps. Still further, the separated step rails 160 could be automatically moved to deploy steps 150 upon unfolding of the section. This could be accomplished by utilizing hinge 400 shaft 410 to transmit a torque applied by a user to unfold the ladder sections (e.g., ladder sections 110, 120) to step rails 160 through one or more linkage members (not shown) and/or gears connected to the hinge 400 shaft 410. The linkage member(s), in one aspect, would be configured to produce an angular step rotation in proportion to a fraction of the rotation of the ladder rails 105, 106. For example, a 180° rotation of ladder rails 105, 106 could be used to effect a 135° rotation of steps 150.
In another aspect of the above example eliminating step rail 160 joints 165, the step rails themselves could be omitted from one or more ladder sections (e.g., upper section 110, middle section 120, and/or lower section 140) in favor of alternative automatic step positioning systems. In one example of an alternative automatic step positioning system, a rack and pinion system could be disposed on an inner surface of ladder rails 105, 106 with a pinion connected to hinge 400 shaft 410 and a rack translatable linearly along a longitudinal axis of the ladder rails. The rack could simultaneously co-act with gears mated to each of the step bars 151. When rotation of the ladder sections is complete and the hinge 400 is locked, the pinion, rack, gears, and steps are also locked in place. The material, strength and duty ratings of the aforementioned pinion, rack, and gears would depend largely upon the step configurations and loads imposed by a user thereupon. The greater the potential torque that may be applied by a user stepping on a distal edge of the step, the higher the strength of the load bearing components must be to prevent component strain or failure. In one aspect, bar 151 may be disposed through a center of the step 150 to bi-sect the step and minimize torque. In another example of an alternative automatic step positioning system, a pulley system utilizing high tensile strength wire or cable (e.g., piano wire having a tensile strength of 3.0–5.5 (Scifer) GPa or high-strength (HS) or ultra high strength (UHS) carbon fiber having tensile strengths of between 2.8–5.2 GPa) could be disposed internally to ladder rails 105, 106 to the same effect as the aforementioned examples.
In the example illustrated in
Alternate configurations could dispose protuding members on one ladder rail to slidingly mate within a C-channel formed in an opposing ladder rail. The sliding or telescoping motion may be facilitated by one or more bearing surfaces possessing a low coefficient of friction or having a low-friction coating applied thereto. For example, end caps 700, 710 comprise a protrusion, such as a pin or annular member, formed of an acetal, PTFE, nylon, polyethylene, or other low friction material, configured to slide within a corresponding groove formed in an upper ladder rail.
Still further, the sliding or telescoping motion may be facilitated by rollers provided on one of the middle ladder rails or the upper ladder rails. One or more rollers or bearing surfaces may be distributed along a length of the respective upper ladder rail and/or middle ladder rail, as necessary, to provide smooth movement of the ladder sections relative to one another. Any two ladder sections may be configured to telescope or translate with respect to one another. For example, a lowermost set of ladder rails may be configured to telescope with respect to a middle set of ladder rails or a plurality of pairs of ladder sections (e.g., three or more) may be configured to telescope or translate with respect to one another. Thus, in accord with the present concepts, a stowable ladder bearing one or more rotatable steps may include any number of ladder sections joining by any combination of rotatable joints (e.g., a hinge) and translatable joints 600 (e.g., a telescoping sections connected by bearing surface(s) or roller(s)).
Movement of one ladder section (e.g., 110) relative to another ladder section (e.g., 120) may be regulated by placement of stops (e.g., 750, 760) at selected locations. As shown in
In another configuration of telescoping upper and lower ladder sections, blocks of almost any solid material (e.g., Delrin® AF) may be used within or adjacent a track or groove provided to receive and stop a corresponding pin, protrusion, or roller element, for example, to thereby limit the range of travel of the translatable joint 600. The blocks may be positioned using any conventional fastening means, such as a mechanical connector (e.g., screw). In another example, rivets may be driven into predetermined locations on the track or groove. Further, the track or groove itself may be narrowed, gradually (e.g., linear or curved transition) or abruptly (e.g., crimping), at opposite ends to provide an impediment to travel of the cylindrical pin, annular member, or roller. A gradual, linear reduction in the dimension of one or more surfaces the track or groove would permit, for example, adjustment of the range of travel of the bearing member by selection of alternative bearing members having a smaller corresponding dimension.
The present disclosed herein can be practiced by employing conventional materials, methodology and equipment. Accordingly, the details of such materials, equipment and methodology are not set forth herein in detail. In the previous descriptions, numerous specific details of one preferred example, such as specific materials, structures, etc., are set forth to provide a grounding in the present concepts. However, it should be recognized that the present concepts can be practiced without resorting to the details specifically set forth. In other instances, well known processing structures have not been described in detail, in order not to unnecessarily obscure the present invention. It is to be understood that the present concepts are capable of use in various other combinations and environments and is capable of changes or modifications within the scope of the inventive concepts expressed herein.
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Number | Date | Country | |
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20050029043 A1 | Feb 2005 | US |