NL2013338B1 - Telescopic ladder assembly. - Google Patents
Telescopic ladder assembly. Download PDFInfo
- Publication number
- NL2013338B1 NL2013338B1 NL2013338A NL2013338A NL2013338B1 NL 2013338 B1 NL2013338 B1 NL 2013338B1 NL 2013338 A NL2013338 A NL 2013338A NL 2013338 A NL2013338 A NL 2013338A NL 2013338 B1 NL2013338 B1 NL 2013338B1
- Authority
- NL
- Netherlands
- Prior art keywords
- ladder
- rung
- section
- ladder section
- locking
- Prior art date
Links
- 125000006850 spacer group Chemical group 0.000 claims abstract description 89
- 230000007246 mechanism Effects 0.000 claims description 52
- XAGFODPZIPBFFR-UHFFFAOYSA-N aluminium Chemical compound [Al] XAGFODPZIPBFFR-UHFFFAOYSA-N 0.000 claims description 5
- 229910052782 aluminium Inorganic materials 0.000 claims description 5
- 238000001746 injection moulding Methods 0.000 claims description 4
- 238000000034 method Methods 0.000 claims description 4
- 230000000712 assembly Effects 0.000 claims description 2
- 238000000429 assembly Methods 0.000 claims description 2
- 230000004913 activation Effects 0.000 abstract description 5
- 230000003993 interaction Effects 0.000 abstract 1
- 239000004411 aluminium Substances 0.000 description 4
- 230000008878 coupling Effects 0.000 description 3
- 238000010168 coupling process Methods 0.000 description 3
- 238000005859 coupling reaction Methods 0.000 description 3
- 230000009286 beneficial effect Effects 0.000 description 2
- 210000003811 finger Anatomy 0.000 description 2
- 230000003213 activating effect Effects 0.000 description 1
- 230000009194 climbing Effects 0.000 description 1
- 210000003813 thumb Anatomy 0.000 description 1
Classifications
-
- E—FIXED CONSTRUCTIONS
- E06—DOORS, WINDOWS, SHUTTERS, OR ROLLER BLINDS IN GENERAL; LADDERS
- E06C—LADDERS
- E06C1/00—Ladders in general
- E06C1/02—Ladders in general with rigid longitudinal member or members
- E06C1/04—Ladders for resting against objects, e.g. walls poles, trees
- E06C1/08—Ladders for resting against objects, e.g. walls poles, trees multi-part
- E06C1/12—Ladders for resting against objects, e.g. walls poles, trees multi-part extensible, e.g. telescopic
- E06C1/125—Ladders for resting against objects, e.g. walls poles, trees multi-part extensible, e.g. telescopic with tubular longitudinal members nested within each other
Abstract
The invention relates to a telescopically extendable and collapsible ladder assembly having a top ladder section, a bottom ladder section, and intermediate ladder sections, wherein a rung of the ladder sections is provided at each end with a spacer, which spacers are located at the top side of their rung and against a stile member of the adjacent upper ladder section, and at their top end have a slanted actuating surface, and wherein sliding automatic release actuators are provided, having a slanted actuating surface for interaction with said actuator surfaces of the spacers, such that, when a rung is moved towards the rung of an adjacent lower ladder section, the activation surfaces of the spacers first contact the actuating surfaces of the release actuators, pushing them into an unlocking position, and subsequently contact support surfaces of the adjacent rung, positioning the rung at an anti-finger pinching distance.
Description
TELESCOPIC LADDER ASSEMBLY
The present invention relates to a telescopically extendable and collapsible ladder assembly having a top ladder section, a bottom ladder section, and one or more intermediate ladder sections.
The top ladder section and each of the one or more intermediate ladder sections have two tubular stile members arranged parallel to each other and interconnected at a top end by a ladder rung to form a U-shaped ladder section. The bottom ladder section has two tubular stile members arranged parallel to each other and interconnected by a top ladder rung and a bottom ladder rung.
The ladder rungs are made from an aluminium tubular profile, for example an extruded aluminium profile, the profile including a top wall, a bottom wall, as well as a front and a back wall extending between the top wall and the bottom wall.
Each ladder section includes a connector at each end of a rung, each connector having a rung portion connected to the end of the rung and a stile member portion connected to one of the stile members of the ladder section.
The stile members of the top ladder section and of the one or more intermediate ladder sections are telescopically inserted into the stile members of an adjacent lower ladder section, so that the one or more intermediate ladder sections and the top ladder section can be collapsed in a collapsing direction towards the bottom ladder section.
The top rung of the bottom ladder section and the rung of each of the one or more intermediate ladder sections are provided at each end with a spacer for, when the ladder assembly is in a collapsed condition, supporting the adjacent upper ladder rung at a predetermined anti-finger pinching distance from the ladder rung on which the spacer has been provided. This, to prevent fingers from getting pinched between the ladder rungs when the ladder assembly is brought into its collapsed position. In an embodiment, this anti-finger pinching distance is for example 2 cm measured between the top wall of a ladder rung and the bottom wall of an adjacent upper ladder rung.
The top rung of the bottom ladder section and the rung of each of the one or more intermediate ladder sections are provided at each end with an automatic latch mechanism, the automatic latch mechanisms being adapted for automatically locking the stile members of the adjacent higher ladder section in a fully extended position of said adjacent higher ladder section. Typically, such a latching mechanism comprises a locking pin biased by a spring element into a locking position, in which locking position the pin is inserted into overlapping openings in the style members. It is observed that latching mechanisms are generally known in the prior art, and are therefore not elaborated upon herein.
The automatic latch mechanisms of the intermediate ladder sections each comprise a locking pin, which locking pins are each moveably supported for movement along a rung in a longitudinal direction thereof, between a locking positon, in which an end of the locking pin is inserted in an opening provided in the stile member of the adjacent upper ladder section to lock the stile members relative to each other, and an unlocking position, in which said end of said locking pin is retracted from said opening, and wherein each locking pin is biased towards the stile member, i.e. towards the locking position.
The automatic latch mechanisms of the intermediate ladder sections each comprise an automatic release actuator, which automatic release actuators are coupled with the locking pin of the automatic latch mechanisms, for unlocking the stile member of an adjacent higher ladder section by moving the automatic release actuator from its passive positon into its actuated position, and thus moving the locking pin from its locking position into its unlocking position, in order to allow for collapsing of the ladder assembly.
The automatic latch mechanisms of the bottom ladder section each comprise a manually operable release actuator, which manually operable release actuators are coupled with the locking pin of the automatic latch mechanisms, for unlocking the stile member of an adjacent higher ladder section by moving the locking pin into its unlocking position, in order to allow for collapsing of the ladder assembly.
The use of spacers if for example shown in patent publication US20070209875, which discloses a collapsible ladder assembly of which the ladder rungs are at their opposite ends provided with spacers to keep the ladder rungs at a predetermined anti-finger pinching distance when the ladder assembly is in its collapsed position. The automatic latching mechanisms provided at the opposite ends of the ladder rungs are manually operated by way of push buttons located in the front wall of each ladder rung.
It is also generally known from the prior art to provide the automatic latching mechanisms with automatic release actuators to allow for automatic release of the automatic latching mechanisms and collapsing of the ladder assembly. For example patent publication W09115651 discloses an auto release mechanism in the form of triangular shaped actuators on the top side of a ladder rung, which actuators cooperate with part of the locking pin of the automatic latching mechanism of the adjacent upper ladder rung. The actuators push the locking pin into its unlocking positon when the adjacent upper ladder rung is moved towards the ladder rung on which the actuators are provided. EP2634360 discloses a ladder assembly in which a spacer and an actuator for automatic release of the automatic latching mechanism of an adjacent upper ladder rung have been combined. The actuators for the pivot type automatic release actuators have been mounted upon the spacer body. A draw back of the prior art is that spacers and actuators for automatic release actuators are often provided as separate elements. When they are combined this is simply an agglomerate of known types of spacers and actuators and thus take up extensive space inside the rung. This is a draw back, since the available space within a rung is limited.
It is an object of the invention to provide a ladder assembly comprising spacers and automatic release actuators that are integrated such that they require little space within the rungs, preferably such that they can be provided below a locking pin of an automatic latching mechanism.
According to the present invention, this object is achieved by providing a ladder assembly according to claim 1.
According to the invention, the ladder assembly is characterized in that the spacers are each located at the top side of their ladder rung and against a stile member of the adjacent upper ladder section, and each extend along said stile member in an upward direction between a base, which base is located at the top of the rung, and a top end, which top end is provided with a slanted actuating surface, which actuating surface is at its top end located adjacent the stile member and veers away from the stile member in the downward direction, wherein the ladder rung of an intermediate ladder section is at its bottom side at both ends provided with a slanted support surface, extending parallel to and vertically above the actuating surfaces of the spacers of the adjacent lower ladder section, such that when the ladder assembly is in its collapsed positon, the support surfaces rest against the actuating surface of the spacers of the adjacent lower ladder section, to keep the ladder rungs at a predetermined anti-finger pinching distance, wherein the automatic release actuators are sliding actuators moveably supported for movement along a rung in a longitudinal direction thereof, and wherein the automatic release actuators are each provided with a slanted actuating surface extending parallel to the actuating surface of the spacer of the adjacent lower ladder section, and wherein said actuating surface of the release actuator, when the automatic release actuator is in its rest position, is located vertically above the actuating surfaces of the spacers of the adjacent lower ladder section, and wherein, when a ladder rung is moved towards the ladder rung of an adjacent lower ladder section, the activation surfaces of the spacers of the ladder rung of the adjacent lower ladder section first contacts the actuating surfaces of sliding automatic release actuators, pushing the sliding automatic release actuators into their unlocking position, and subsequently contact the support surfaces of the ladder rung, positioning the ladder rung at a predetermined anti-finger pinching distance from the ladder rung of the adjacent lower ladder section.
Each spacer is provided with an actuating surface for both activating the release mechanism of an adjacent upper ladder rung and for supporting the adjacent upper ladder rung at an anti-finger pinching distance from the ladder rung. To enable the spacer to release the latching mechanism of the adjacent upper ladder rung as well as support the rung at a predetermined anti-finger pinching distance from the rung the spacer is provided on, the sliding release actuator is positioned with its actuating surface between the actuating surface of the spacer and the support surface of the adjacent upper ladder rung, when the latch mechanism of the upper adjacent ladder rung is locked.
Thus, providing a spacer with an actuating surface for both engaging the support surface of the adjacent upper ladder rung and for engaging the actuating surface of a release mechanism of that upper ladder rung, which actuating surface is provided below that support surface, allows for a compact configuration of the spacer and release mechanism which does not require much space inside the rung of the ladder section.
In an embodiment, the ladder stile members each have a circular cross section comprising a flat section facing the rung, which flat section extend substantially perpendicular to a longitudinal axis of the rung, and wherein the spacers are each positioned against this flat section of the ladder stile members. The flat wall section of the stile member provides an optimal lateral support for the spacers, and prevents the spacers from is provided with a flat wall section for supporting the spacer in a lateral direction. This is beneficial since the spacers, during the collapse of the ladder assembly, are subjected to a substantial load when they block the adjacent upper ladder section at a predetermined anti-finger pinching distance from further advancing. Because both the actuating surface of the spacer and the support surface of the adjacent upper ladder rung extend at an angle with the stile members of the ladder, a substantial part of the compressive forces exerted onto the spacer, either on impact when the ladder sections are moved into their collapsed position or when the ladder is in its collapsed positon, is directed in a lateral direction towards the stile member. This reduces the chance that the spacer gets damaged. When the stile member is provided with a flat contact surface, this load can be optimally transferred from spacer to stile member.
In a further embodiment, the flat wall section is provided with a central recess, extending along the length of the stile member, and the spacers are partially located in said recess. Such a recess provides additional support for the spacer.
In an embodiment, the support surfaces of a ladder rung are located below the locking pins of the latching mechanism of said ladder rung, preferably centrally below the locking pins. It is observed a latching mechanism typically comprises a single locking pin, which locking pin located at the center of the rung. By providing a sliding release actuator with an activation surface located below the support surface, the invention enables to provide the support surface below the pin and thus locate the spacer at the center of the rung, which in turn provides a compact configuration of the spacer, automatic release actuator, latch mechanism assembly.
It is observed that the invention thus allows for providing the slanted actuating surface of the automatic release actuator and the slanted support surface of the adjacent upper ladder rung below the locking pin, which is typically provided in the center of the rung. Thus, the invention allows for a providing the spacers in a central position on a rung, i.e. directly below the locking pin when seen in top view. This positon of the spacer allows for providing a narrow spacer which preferably is combined with stile members having a flat section that functions flat support surface for said spacer, as was explained above. It is noted that a centrally mounted spacer allows for providing the stile member with a relative narrow flat support surface for said spacer. 4. In an alternative embodiment, the support surfaces of a ladder rung are located level with or even above the locking pins of the latching mechanism of said ladder rung. In such an embodiment, the automatic release slide is located, when seen in top view, adjacent the pin. In a further embodiment, each latch mechanism is provided with two automatic release slides, one at each side of the locking pin. Preferably both the slides are located lateral of and adjacent to the locking pin. In such an embodiment, the spacer is provided with two top ends, for example is substantially U-shaped, which two top end each engage an actuating surface of the automatic release slide, and, when the ladder assembly is in a collapsed condition, extend in the upward direction on the opposite sides of the locking pin.
In a further embodiment, the automatic release actuator is provided with a single slide, which slide moveably supports the locking pin, and extends on both sides of the locking pin in a lateral direction. Such a slide is preferably provided with two actuating surfaces, one on each side of the locking pin. 5. In an embodiment, the connector is made out of plastic using the injection moulding technique, and wherein the connector is at its top provided with a spacer, and at its bottom side provided with the support surface, which spacer and support surface form an integral part with the connector.
In an embodiment, the locking pin is reciprocally supported in the connector member, e.g. with a spring between the locking pin and the connector member to bias the pin toward its locking position, and each connector member is provided with an actuator connected to the locking pin, e.g. to allow actuation thereof by a thumb of a user or to allow for actuation by contact with a lower positioned ladder section. 6. In an embodiment, each rung is provided with a recess comprising the support surface, which recess preferably is a one side open chamber in the bottom of the connector, wherein the support surface forms the top wall of a said chamber, and wherein one sidewall of the chamber is formed by the stile member. 7 In an embodiment the sliding automatic release actuators are provided below the rung, i.e. on the outside thereof, and extend through a slot in the bottom wall of the rung and/or connector into the interior of the rung and/or connector. In this embodiment, the actuating surface of the automatic release actuators is thus also provided outside the ladder rung and the connector. The automatic release actuators each have an extension, entering the rung and/or connector, for coupling the actuator with the locking pin, for example include a snap provision adapted to snap around a rod-shaped locking pin. In an embodiment, the automatic release actuator is made out of plastic using the injection moulding technique.
In an alternative embodiment, the automatic release actuators are provided inside the rung, for example are slideable supported in the connector, which part of the connector is inserted into a cylindrical rung body, for example an aluminium extruded ladder rung. 8 In an embodiment, the ladder rungs are at their bottom side provided with an elongated recessed portion extending over the length thereof, and the automatic release actuators are arranged in said recessed portion. Thus, the automatic release actuators are substantially protected from accidental contact with a hand or food of a person climbing the ladder, which contact, if forcefully, may damage the automatic release actuator and/or its functioning. 9 In an embodiment, each connector is at it’s stile member portion provided with a ring shaped section for receiving the stile member of a ladder section, which is to be inserted into the ladder rung.
In an alternative embodiment, the stile member portion of the connectors comprises a front and a rear collar segment, each integral at one end thereof with the rung portion, the two collar segments substantially encircling the stile member, the collar segments having spaced apart opposed ends, a fastener being provided bridging the opposed ends of the collar segments for securely coupling the collar segments around the stile member, 10 In an embodiment, the rung of each intermediate ladder section is, in addition to the automatic release actuators, provided with one or more manually operable release actuators connected to the latch mechanisms of the rung to allow for manual unlocking of the stile members of said adjacent higher ladder section by a user in order to allow for a section-by-section manually release and collapsing of the ladder assembly.
It is observed that the slanted actuating surfaces and support surfaces preferably make an angle with the horizontal of at least 35 degrees, preferably an angle in the range of 40-70, more preferably in the range of 40-60 degrees, for example an angle of about 45 degrees.
The invention furthermore provides a loft ladder including a ladder assembly according to the invention.
The invention furthermore provides a stepladder having a first stepladder assembly and a second stepladders assembly hinged to one another so as to be in a storage position folded against one another and an operative position similar to an inverted V at least one of the stepladder assemblies being a ladder assembly according to the invention.
The invention furthermore provides a work platform including a ladder assembly according to the invention.
Advantageous embodiments of the ladder assembly according to the invention are disclosed in the subclaims and in the description, in which the invention is further illustrated and elucidated on the basis of a number of exemplary embodiments, of which some are shown in the schematic drawing.
In the drawings
Fig. 1 shows a frontal view of a telescopic extendable and collapsible ladder assembly according to the invention, in an extended condition;
Fig. 2 shows a frontal view in close up of two ladder rungs, each connected to a stile member via a connector, of the ladder assembly of Fig. 1;
Fig. 3 shows perspective view from below of a top rung of a bottom ladder section and an adjacent upper ladder section a partially inserted in said bottom ladder section,
Fig. 4 shows a further perspective view from below of the bottom ladder section and an adjacent upper ladder section of Fig. 3,
Fig. 5 shows a frontal view of the bottom ladder section and an adjacent upper ladder section of Fig. 3, with the adjacent upper ladder section further inserted in the bottom ladder section,
Fig. 6 shows a perspective view from below of the bottom ladder section and an adjacent upper ladder section of Fig. 5,
Fig. 7 shows a perspective view from above of a connector of a ladder assembly according to the invention,
Fig. 8 shows a perspective view from below of a connector of the connector of Fig. 7,
Fig. 9 shows a perspective view from below of a connector of automatic release actuator of a ladder assembly according to the invention,
Fig. 10 shows a perspective top view from above of the automatic release actuator of fig. 9, and
Fig. 11 shows a frontal view in cross section of the bottom ladder section and the adjacent upper ladder section of Fig. 5.
Fig. 1 shows a frontal view of a telescopic extendable and collapsible ladder assembly 1 according to the invention, in an extended condition. The ladder assembly 1 has a top ladder section 2, a bottom ladder section 3, and multiple intermediate ladder sections 4.
The stile members of the top ladder section 2 and of the one or more intermediate ladder sections 4 are telescopically inserted into the stile members of an adjacent lower ladder section, so that the multiple intermediate ladder sections and the top ladder section can be collapsed in a collapsing direction towards the bottom ladder section.
The top ladder section 2 and each of the multiple intermediate ladder sections 4 have two tubular stile members 5 arranged parallel to each other and interconnected at a top end by a ladder rung 6 to form a U-shaped ladder section. The bottom ladder section 3 has two tubular stile members 5 arranged parallel to each other and interconnected by a top ladder rung 6’ and a bottom ladder rung 6”.
The ladder rungs 6,6’,6” are made from an aluminium tubular profile, the profile including a top wall, a bottom wall, as well as a front and a back wall extending between the top wall and the bottom wall.
Fig. 2 shows a frontal view in close up of two ladder rungs 6 of the ladder assembly of Fig. 1. Each ladder rung is connected to a stile member 5 via a connector 7. Each ladder section 2,3,4 includes a connector 7 at each end of a rung 6,6’,6”. Fig. 7 shows a perspective view from above of a connector 7 of a ladder assembly according to the invention. Fig. 8 shows a perspective view from below of a connector of the connector of Fig. 7. The connector 7 has a rung portion 8, in use connected to the end of a ladder rung, and a stile member portion 9, in use connected to one of the stile members of a ladder section.
In the exemplary embodiment shown, the connector is at it’s stile member portion 9 provided with a ring shaped section for receiving the stile member 5 of a ladder section, which is to be inserted into the ladder rung.
The top rung 6’ of the bottom ladder section 3 and the rung 6 of each of the multiple intermediate ladder sections 4 are all provided at, each end of the ladder rung 6’,6, with a spacer 10 for, when the ladder assembly 1 is in a collapsed condition, supporting the adjacent upper ladder rung 6 at a predetermined anti-finger pinching distance from the ladder rung 6’,6” on which the spacer has been provided. This, to prevent fingers from getting pinched between the ladder rungs when the ladder assembly is brought into its collapsed position. In an embodiment, this anti-finger pinching distance is for example 2 cm measured between the top wall of a ladder rung and the bottom wall of an adjacent upper ladder rung.
The top rung 6’ of the bottom ladder section 3 and the rung 6 of each of the multiple intermediate ladder sections 4 are provided at each end with an automatic latch mechanism 11. The automatic latch mechanisms 11 are adapted for automatically locking the stile members 5 of the adjacent higher ladder section in a fully extended position of said adjacent higher ladder section. Fig. 11 shows a frontal view in cross section of the bottom ladder section 3 and the adjacent upper ladder section 4, also shown in Fig. 5, in which the automatic latching mechanism 11 provided at the end of the ladder rung of the intermediate ladder section is visible.
The automatic latching mechanisms in the ladder rungs of the ladder assembly 1 are typically all substantially similar in design. The automatic latch mechanisms 11 comprise a locking pin 12, which locking pin is moveably supported for movement along a rung 6’,6 , i.e. in a longitudinal direction thereof, between a locking positon, in which an end of the locking pin 12 is inserted in an opening provided in the stile member 5 of the adjacent upper ladder section to lock the stile members 5 relative to each other, and an unlocking position, depicted in Fig. 11, in which said end of said locking pin 12 is retracted from said opening. Each locking pin 12 is biased towards the stile member, i.e. towards the locking position, preferably by way of a spring element, for example a helical spring 13 as depicted in Fig. 11. A manually operable release actuator and/or an automatic release actuator are/is provided for moving the locking pin into its unlocking position.
In the exemplary embodiment shown, the sliding automatic release actuators 14 are provided below the rungs 6,6’, i.e. on the outside thereof, and extend through a slot in the bottom wall of the rung and connector, see fig. 11, into the interior of the rung and connector. In this embodiment, the slanted actuating surface 21 of the automatic release actuators 14 is thus also provided outside the ladder rung and the connector. In the particular embodiment shown, the automatic release actuators 14 each have an extension, entering the rung 6 and connector 7, for coupling the automatic release actuator 14 with the locking pin 12. In the embodiment shown, the extension includes a snap provision 23 adapted to snap around the rod-shaped locking pin 23, see figs. 9 and 10.
The skilled person will appreciate that the body of the connector includes a passage for the locking pin (which can form an extension of or be connected to the automatic release actuator) and allows to accommodate the spring 13 for biasing said locking pin 12 towards it’s locked position (the stile member having an associated locking pin opening to receive said locking pin in extended state of the ladder section).
The automatic latch mechanisms 11 of the bottom ladder section 3 each comprise a manually operable release actuator 13, which manually operable release actuators are coupled with the locking pin of the automatic latch mechanisms for unlocking the stile member of an adjacent higher ladder section by moving the locking pin into its unlocking position, in order to allow for collapsing of the ladder assembly.
In the ladder assembly 1 shown, the manually operable release actuators 13 are located centrally on the top ladder rung 6’ of the bottom ladder section. In an alternative embodiment, the manually operable release actuators are for example provided at the ends of the ladder rung, or a single manually operable release actuator, connected with both latching mechanisms, is provided at the centre of the rung.
The automatic latch mechanisms 11 of the intermediate ladder sections 4 each comprise an automatic release actuator 14. These automatic release actuators 14 are coupled with the locking pin 12 of the automatic latch mechanisms 11, for unlocking the stile member of an adjacent higher ladder section by moving the automatic release actuator from its rest positon, shown in Figs. 2, 3 and 4, into its actuated position, shown in figs 5, 6 and 11, and thus moving the locking pin from its locking position into its unlocking position, in order to allow for collapsing of the ladder assembly,
According to the invention, the spacers 10 of the ladder assembly 1 are each located at the top side of their ladder rung 6,6’ and against a stile member 5 of the adjacent upper ladder section. For example in fig. 11 it is clearly shown that the spacer rests against the outer surface of the stile member of the adjacent upper ladder section. Thus, when the adjacent upper ladder section is moved towards its collapsed position, it slides along the spacer. The spacers 10 each extend along the stile member in an upward direction between a base 15, which base 15 is located at the top of the rung, and a top end 16, which top end is provided with a slanted actuating surface 17. The slanted actuating surface 17 is at its top end 18 located adjacent the stile member and veers away from the stile member 5 in the downward direction.
According to the invention, the ladder rung 6, e.g. the part of a connector that forms part of the rung, of an intermediate ladder section is at its bottom side at both ends provided with a slanted support surface 19, extending parallel to and vertically above, i.e. in a vertical projection or directly above, the slanted actuating surfaces 17 of the spacers 10 of the adjacent lower ladder section, such that when the ladder assembly is in its collapsed positon, the support surfaces 19 rest against the actuating surfaces 17 of the spacers 10 of the adjacent lower ladder section, as shown in Fig. 11, to keep the ladder rungs at a predetermined anti-finger pinching distance.
In the exemplary embodiment shown, the connector 7 is at its top provided with a spacer 10, and at its bottom side provided with the slanted support surface 19. Furthermore, the connector 7 is made out of plastic using the injection moulding technique, and the spacer 10 and support surface 19 form an integral part with the connector.
Furthermore, in the exemplary embodiment shown, the rung is provided with a recess comprising the support surface 19. The recess is a one side open chamber 20 in the bottom of the connector 7. The support surface 19 forms the top wall of the chamber 20, and one sidewall of the chamber 20 is formed by the stile member 5, see fig. 8 and fig. 11.
According to the invention, the automatic release actuators 14 are sliding actuators which are moveably supported for movement along a rung, in a longitudinal direction thereof.
Furthermore, the automatic release actuators 14 are each provided with a slanted actuating surface 21 extending parallel to the slanted actuating surface 17 of the spacer 10 of the adjacent lower ladder section. When the automatic release actuator 14 is in its rest position, the actuating surface 17 of the release actuator 14 is located vertically above, i.e. in a vertical projection or directly above, the slanted actuating surface 17 of the spacer 10 of the adjacent lower ladder section, see for example figs. 2-4.
When a ladder rung 6 is moved towards the ladder rung 6’ of an adjacent lower ladder section 3, compare Figs 3 and 4 with figs. 5 and 6, the slanted activation surfaces 17 of the spacers 10 of the ladder rung 6’ of the adjacent lower ladder section 3 first contacts the slanted actuating surfaces 21 of sliding automatic release actuators, pushing the sliding automatic release actuators into their unlocking position, and subsequently contact the slanted support surfaces 19 of the ladder rung 6, positioning the ladder rung 6 at a predetermined anti-finger pinching distance from the ladder rung 6’ of the adjacent lower ladder section 3.
Thus, according to the invention, the spacers 10 are each arranged such that - during collapse of the ladder assembly 1 - they cooperates with an automatic release actuator 14 of an automatic latch mechanism 11 arranged on an adjacent upper ladder section 4, the locking pin 12 of that locking mechanism being initially biased into its locking position and being moved by said cooperation with the slanted actuating surface 21 against said bias into an unlocking position, said locking pin in said unlocking position allowing for the passage of the stile member of the adjacent ladder section during collapse of the ladder section assembly.
It is observed that in the exemplary embodiment shown, the slanted support surfaces 19 of a ladder rung are located below the locking pins 12 of the latching mechanism of the ladder rung, more in particular are located centrally below the locking pins, see for example Fig. 8. By providing a sliding release actuator with an activation surface located below the support surface, the invention enables to provide the support surface below the pin and thus locate the spacer at the center of the rung, which in turn provides a compact configuration of the spacer, automatic release actuator, latch mechanism assembly.
In the exemplary embodiment shown, the ladder stile members 5 each have a circular cross section comprising with a flat section 22 facing the ladder rung 6,6’,6”. The flat section 22 extends perpendicular to a longitudinal axis of the ladder rung 6,6’,6”. The flat wall section 22 of the stile members 5 provides an optimal lateral support for the spacers 10, which are each positioned against this flat section of the ladder stile members. This is beneficial since the spacers 10, during the collapse of the ladder assembly, are subjected to a substantial load when they block the adjacent upper ladder section at a predetermined anti-finger pinching distance from further advancing. Because both the actuating surface of the spacer and the support surface of the adjacent upper ladder rung extend at an angle with the stile members of the ladder, a substantial part of the compressive forces exerted onto the spacer, either on impact when the ladder sections are moved into their collapsed position or when the ladder is in its collapsed positon, is directed in a lateral direction towards the stile member. This reduces the chance that the spacer gets damaged. When the stile member is provided with a flat contact surface, this load can be optimally transferred from spacer to stile member.
It is observed that the invention allows for providing the actuating surface of the automatic release actuator and the support surface of the adjacent upper ladder rung below the locking pin, see Fig. 11, which is typically provided in the center of the rung. Thus, the invention allows for a providing the spacers in a central position on a rung, i.e. directly below the locking pin when seen in top view. This positon of the spacer allows for providing a narrow spacer, and thus or providing the stile member with a relative narrow flat support surface for said spacer.
REFERENCE SIGNS 01 ladder assembly 02 top ladder section 03 bottom ladder section 04 intermediate ladder sections 05 stile member 06 ladder rung 06’ top ladder rung 06” bottom ladder rung 07 connector 08 ladder rung portion connector 09 stile member portion connector 10 spacer 11 automatic latch mechanism 12 locking pin 13 manually operable release actuators 14 automatic release actuators 15 base of spacer 16 top end of spacer 17 slanted actuating surface spacer 18 top end slanted actuating surface of spacer 19 slanted support surface ladder rung 20 one side open chamber in bottom side connector 21 slanted actuating surface of automatic release actuators 22 flat section stile member 23 extension automatic release actuator 24 spring element
Claims (13)
Priority Applications (8)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
NL2013338A NL2013338B1 (en) | 2014-08-18 | 2014-08-18 | Telescopic ladder assembly. |
US15/502,251 US10161184B2 (en) | 2014-08-18 | 2015-08-17 | Telescopic ladder assembly |
CN201580050755.5A CN107075905B (en) | 2014-08-18 | 2015-08-17 | Telescopic ladder assembly |
PCT/NL2015/050579 WO2016028147A2 (en) | 2014-08-18 | 2015-08-17 | Telescopic ladder assembly |
CN201910455556.2A CN110344747B (en) | 2014-08-18 | 2015-08-17 | Telescopic ladder assembly |
EP15790298.2A EP3183410B1 (en) | 2014-08-18 | 2015-08-17 | Telescopic ladder assembly |
EP19187861.0A EP3581754B1 (en) | 2014-08-18 | 2015-08-17 | Telescopic ladder assembly |
US16/183,999 US10480245B2 (en) | 2014-08-18 | 2018-11-08 | Telescopic ladder assembly |
Applications Claiming Priority (1)
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NL2013338A NL2013338B1 (en) | 2014-08-18 | 2014-08-18 | Telescopic ladder assembly. |
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NL2013338B1 true NL2013338B1 (en) | 2016-09-22 |
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NL2013338A NL2013338B1 (en) | 2014-08-18 | 2014-08-18 | Telescopic ladder assembly. |
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NL (1) | NL2013338B1 (en) |
Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
DE202012100131U1 (en) * | 2012-01-13 | 2012-04-03 | Fengruo Ying | Locking device for retractable or extendable ladder |
DE202012104992U1 (en) * | 2012-12-20 | 2013-01-15 | Xiaoling Chen | telescopic ladder |
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2014
- 2014-08-18 NL NL2013338A patent/NL2013338B1/en not_active IP Right Cessation
Patent Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
DE202012100131U1 (en) * | 2012-01-13 | 2012-04-03 | Fengruo Ying | Locking device for retractable or extendable ladder |
DE202012104992U1 (en) * | 2012-12-20 | 2013-01-15 | Xiaoling Chen | telescopic ladder |
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