The present invention relates to a rung for use in a ladder section of a collapsible ladder which comprises several ladder sections, where each ladder section comprises two ladder tubes arranged parallel to each other and interconnected by a rung to form the ladder section. Each ladder tube is telescopically inserted into a ladder tube of a lower ladder section to form the collapsible ladder. The present invention also relates to an improved telescopic or collapsible ladder or a stepladder.
As well known by persons skilled in the art of collapsible ladders, such ladders usually comprise a number of tube portions having various diameters and which hence are telescopically insertable into one another. Every upper end of any of the tube portions are fastened to one end of a ladder step, whereas the other end of the ladder step is fastened to an upper end of a tube portion having the same diameter, the two tube portions and the ladder step forming a ladder section, the tube sections of which being insertable into an adjacent ladder section comprising tube portions having a larger diameter.
The resulting ladder can hence be collapsed by inserting higher ladder sections into lower ladder sections, and the ladder can be extended by extracting higher ladder sections from the lower ladder sections. A pin extending through the holes in the outer walls of two adjacent tube portions locks the tube portions to prevent the extended ladder from collapsing. Ladders having collapsible and expandable ladder sections are used in order to make the ladder smaller for storage and transport purposes.
The manufacturing process of a rung and the collapsible ladder to which will be attached involves several steps. Due to the construction of the rungs in prior art, the manufacturing and assembly process is complex. Furthermore, the durability of the collapsible ladder is always a quality that needs to be improved.
It is the object of the present invention to provide a rung and a collapsible ladder where the construction is simplified and the ladder is more durable.
An object of the present invention is to provide a rung for a collapsible ladder which simplifies the assembly of the collapsible ladder while simultaneously making the ladder more durable.
According to a first aspect, a rung for use in a ladder section of a collapsible ladder is provided. The collapsible ladder comprises several ladder sections, where each ladder section comprises two ladder tubes arranged parallel to each other and interconnected by a rung to form the respective ladder section. Each ladder tube is telescopically inserted into a ladder tube of a lower ladder section to form the collapsible ladder. The rung comprises a main section, a first bracket section and a second bracket section, wherein the first and second bracket sections are arranged at each end of the rung to receive the respective ladder tube. The rung is characterized in that the main section and the first and second bracket sections are provided as an integrated unit.
The feature of the rung being formed as an integrated unit provides several benefits to the construction of the collapsible ladder. For example, since the new improved ladder consists of fewer separate parts the assembly of the collapsible ladder is simplified. The production time is thus decreased leading to lower productions cost.
Furthermore, in prior art system the first and second bracket sections were attached to the main section of the rung using for example by means of press fit. This step of attachment generally causes problem when performing quality tensile tests, since the parts may disconnect from each other. By providing the rung as an integrated unit this problem is diminished. The durability of an integrated rung is increased, especially when quality testing the ladder using tensile tests.
The main section and the first and second bracket sections may be formed by the same material.
The first and second bracket sections may be symmetrical to each other.
The main section may be inclined at an angle to a plane in which said first and second bracket sections extend.
At least a part of the main section may be provided with an outer layer comprising a plurality of depressions or protrusions.
At least a part of the main section may comprise a plurality of depressions or protrusions.
The rung may comprise at least one grip handle. The at least one grip handle may be arranged at a distance d from a central line of the rung, wherein the central line is parallel with the ladder tubes and wherein the central line is perpendicular to a longitudinal line.
The grip handle and the rung may be provided as an integrated unit. The grip handle may be arranged on a bottom plate, wherein the bottom plate is removable arranged to the main section of the rung.
The rung may comprise a locking mechanism. The rung may comprise at least one locking indicator to enable the visualization of whether the locking mechanism is in a locked position or not.
According to a second aspect, a collapsible ladder is provided. The collapsible ladder comprises several ladder sections, each ladder section comprises two ladder tubes arranged parallel to each other and interconnected by a rung to form the respective ladder section, and where each ladder tube is telescopically inserted into a ladder tube of a lower ladder section to form the collapsible ladder. The rung comprises a main section, a first bracket section and a second bracket section, wherein the first and second bracket sections are arranged at each end of the rung to receive the respective ladder tube. The collapsible ladder is characterized the main section of the rung, the first bracket section and the second bracket section are provided as an integrated unit.
According to a third aspect, a collapsible stepladder is provided. The collapsible stepladder comprises a first and a second ladder leg, where the legs are hingedly connected to each other in one end, and where each of the ladder legs comprises several ladder sections. Each section comprises two ladder tubes arranged parallelly to each other and interconnected by a rung to form the respective ladder section. Each ladder tube is telescopically inserted into a ladder of a lower ladder section to form the collapsible stepladder comprising at least three ladder sections. The rung comprises a main section, a first bracket section and a second bracket section, wherein the first and second bracket sections are arranged at each end of the rung to receive the respective ladder tube. The collapsible stepladder is characterized the main section of the rung, the first bracket section and the second bracket section are provided as an integrated unit.
In the following, the invention will be explained with reference to the accompanying drawings, where:
In
A maximally collapsed ladder is shown in
The ladder tubes 10, 12 may be provided with end portions on which the ladder stands. The end portions are thus arranged at the lowest part of the ladder tubes 10, 12. The end portions may be arranged with a material of high friction, thus lowering the risk of the ladder moving during use.
In order to telescopically collapse and expand the ladder, a locking or retaining mechanism may be provided. In the embodiment shown in
In one embodiment the ladder only comprises one pair of actuators which for example are arranged on the front side of the second lowermost rung. The single pair of actuators will still be able to collapse the entire ladder. Alternatively, the ladder comprises a first pair of actuators arranged on the second uppermost ladder rung and a second pair of actuators arranged on a rung positioned between the second uppermost rung and the second lowermost rung. The second pair of actuators enables the lowering of a lower part of a collapsible ladder and the first pair of actuators enables the lowering of an upper part of the collapsible ladder. Such actuators are described in the European patent EP1728966, which is hereby incorporated by reference.
In a further embodiment the pin of the lowest ladder section may be withdrawn from interaction with its respective holes in the tubes of the neighboring ladder section by manipulating a foot control located and arranged to maneuvered by a foot of a user of the ladder. Such a locking mechanism is described in the international application WO20120020333, which is hereby incorporated by reference.
It should be noted that although only some types of locking/retaining mechanisms are mentioned herein, any type of mechanism suitable to collapse and expand a telescopic ladder could be used.
Different embodiments of a cross-sectional shape of a ladder tube are shown in
It is beneficial if the cross-sectional shape has a relatively small cross section area to decrease the material costs. At the same time it is beneficial to have a shape which has a high resistance to bending. The section modulus is highly dependent on the cross sectional shape.
Furthermore the ladder tube 10, 12 should have a form which allows for an easy manufacturing process. The manufacturing process involves several crucial steps, for example extruding the profile which the ladder tube 10, 12 may be constructed from, measuring where the locking holes should be placed and actually perform the manufacturing of the holes. Having a tube 10, 12 with a cross section comprising a straight side 16 improves the quality of the performance of these steps.
The ladder tube 10, 12 may be formed as an extruded aluminum profile. If high temperature extrusion is used for this process, the risk of deformation after the extrusion process is reduced if the tube 10, 12 has a straight section which it can rest while cooling down.
Having a straight section 16 is also beneficial as a reference point during the manufacturing process. Measuring and manufacturing the locking holes requires high precision. A straight section 16 makes it easier to restrain the ladder tube 10, 12 during the measurement and/or manufacturing of the holes and thus increases the precision obtained. The holes may for example be manufactured using punching, drilling, milling or electrical discharge machining. The straight section 16 is thus used as a technical surface during manufacturing.
Having a ladder tube having a cross-section comprising only of straight sections 16 would however not be desirable. Such a construction would be less resistant to bending and would not have a sufficient torsional stiffness. A desirable construction thus has a cross-sectional shape having at least one straight section 16 and at least one additional section which is not straight.
The present inventors have realized, after insightful consideration, that a ladder tube that has a cross-sectional shape comprising only one straight section 16 and at least one additional sections 18a-b being concave a better ladder tube may be provided in a novel and inventive way.
In one embodiment shown in
The present inventors have realized, after insightful consideration, that a ladder tube that has a cross-sectional shape comprising only one straight section 16 and at least three additional sections 18a-e, being non-straight, a better ladder tube may be provided in a novel and inventive way. In an even more preferred embodiment, the ladder tube comprises a five additional sections 18a-18e that all have a convex shape.
In the embodiment shown in
Although not shown, it should be noted that the cross-sectional shape may for example also comprise a combination of two straight sections and four additional sections or three straight sections and three additional sections.
The additional concave sections 18a have the benefits that they provide a better resistance to bending and a higher torsional (or rotational) stiffness. When the ladder tubes are mounted in to a telescoping pipe assembly, the cross-sectional shape will allow the ladder tubes 10, 12 to retain in their position, not doing torsional movement, which makes the whole ladder construction stiff. Hence, there is no need for any additional steering parts to get the ladder tubes to only move linearly. Torsion, i.e. twisting, of the ladder tube 10, 12 is highly undesirable since the plurality of ladder tubes 10, 12 are telescopically arranged.
Furthermore, having a cross-sectional shape comprising one straight section 16 and at least one additional concave section has benefits during the assembly step during the manufacturing process. The assembly process is easier and less prone of mistake thanks to the additional sections 18 being of a different shape than the straight section 16, hence the user performing the assembly of the ladder 1 has reduced possibilities on how to assemble the ladder 1. Thus having the combination of non-straight sections 18 and a straight section 16 in the ladder tube 10, 12 has the benefits that the ladder tube 10, 12 is less likely to be mistakenly arranged in its respective rung 20.
In the embodiment shown in
In one embodiment each rung 20a is arranged to the tube using three rung protrusions 28a-c which each corresponds to a first mounting hole 14, a second mounting hole 15 and a third mounting hole 19. It should be noted that the first, second and third mounting holes 14, 15, 19 may be arranged on other sections than shown herein, depending on the cross-sectional shape of the ladder tube 10, 12.
It should also be noted that the tubes 10, 12 may comprise more holes, for example fastening holes for devices preventing the ladder from being accidently pulled apart.
In
The two bracket sections 24a, 24b may be identical and symmetrical to one another, i.e. the first bracket section 24a could be arranged on either the first or second ladder tube 10, 12.
The rung 20 is provided as a single integrated unit, where the main section 22, the first bracket section 24a and the second bracket section 24b are one single piece. The main section 22 and the first and second bracket sections 24a-b are formed by the same material. The material may for example be a polymer. In one embodiment the material is a thermoplastic material. The thermoplastic material may for example a polyamide, such as for examplenylon. The material may be reinforced by adding compositions of glass fibers.
The feature of the rung 20 being formed as an integrated unit provides several benefits to the construction of the collapsible ladder. For example, since the new improved ladder 1 consists of fewer separate parts the assembly of the collapsible ladder is simplified. The production time is thus decreased leading to lower productions cost.
In prior art system the first and second bracket sections were attached to the main section of the rung using for example by means of press fit. This attachment step generally causes problem when performing quality tensile tests, since the parts may disconnect from each other. By providing the rung 20 as an integrated unit this problem is diminished. The durability of an integrated rung 20 is increased, especially when quality testing the ladder using tensile tests.
The main section 22 of the rung 20 is slightly inclined to provide a more user friendly ladder 1. In one embodiment, the main section 22 is inclined with an angle α with respect to a horizontal plane. The angle α may range between 10 and 20 degrees, and more preferably around 15 degrees.
The main section 22 of the rung comprises a step surface 23, which is the surface which the user is intended to place its feet during use of the ladder. In one embodiment, at least a portion of the step surface 23 of the main section 22 of the rung 20 is provided with a plurality of depressions or protrusions (not shown). The depressions or protrusions may be provided in different patterns, such as for example arranged on a plurality of lines. The individual depressions or protrusions may have the form of a circle, a cube, a line or any other suitable form. These depressions or protrusions provide a rung surface 23 which provides a better grip for the user to stand on. The risk of slipping is therefore decreased. These depressions or protrusions may be constructed in integral with the rest of the rung 20.
In one embodiment, at least a part of the step surface 23 is provided with an outer layer (not shown). The outer layer may be provided with either a plurality of depressions or protrusions arranged in different patterns and/or the outer layer may be a soft layer increasing the comfort for the user standing on the rung 20.
In one embodiment the rung 20 comprises three rung protrusions 28a-c arranged to fit the first, second and third mounting holes 14, 15, 19 of the ladder tube 10, 12. This secures the rung 10, 12 to the ladder tube 10, 12. The rung protrusions 28a-c are each arranged on the rung 20 so that it corresponds to the mounting holes 14, 15, 19 of the ladder tube 10, 12.
In order to facilitate the assembly step in the manufacturing process the rung 20 may additionally or alternatively be arranged to the ladder tube 10, 12 using clamping.
In one embodiment, the clamping function is created by having a slot or slit 31 (shown in
In one embodiment the rung 20 comprises a rung locking hole 29 which together with the locking hole 17 is used to receive a locking pin 27 (see
In
The rung 20 shown in
As shown in
In
Although not shown, the two grip handles 40, 40′ could be arranged at different distances from the central line, for example one handle with a distance d from the central line and the other grip handle with a distance d2 from the central line, where the distance d2 could be either smaller or larger than the distance d.
In one embodiment the grip handle 40 is arranged on the bottom side of the rung as a separate unit. The grip handle and the rung are thus not constructed as a single unit.
In another embodiment the grip handle 40 is arranged in integral with the rung, and thus constructed as a single unit.
In yet another embodiment the grip handle 40 is provided on a bottom plate (not shown), where the bottom plate is removable arranged to the main section 22 of the rung 20. The bottom plate may be constructed in the same material as the rung 20.
Although not shown in the figures, it should be understood by the skilled person that the grip handle 40 may be arranged on only one or several rungs of a collapsible ladder.
The rung 20 shown in
In
In one embodiment the collapsible ladder 1 comprises locking indicators (not shown) on all or some rungs 20a-k. The locking indicator may have a green field to indicate that the locking mechanism associated with that locking indicator is activated and/or a red field to indicate that the locking indicator is inactivated. These indicating fields may be provided on a plate made of plastic or metal attached to the locking indicator. The locking indicator may be completely housed in the rung, but the plate with the green and red fields is visible through a recess in the rung. Alternatively the locking indicator can be arranged as colored portions of the locking pin 27.
Even though it has not been shown by the detailed embodiment or the drawings it is evident that the claimed rung can be used on a stepladder. A collapsible stepladder comprises a first and a second ladder leg. The legs are hingedly connected to each other in one end, and each of the ladder legs can be seen as an individual collapsible ladder.
It should be appreciated that even though numerous characteristics and advantages of the present invention have been set forth in the foregoing description, together with details of the structure and function of the invention, the description is only illustrative and changes may be made in detail, especially in matters of shape, size and arrangement of parts within the scope of the invention to the full extent indicated by the appended claims.
Number | Date | Country | Kind |
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1650454-0 | Apr 2016 | SE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2017/058027 | 4/4/2017 | WO | 00 |