EP0189929A2 - Step ladder - Google Patents

Abstract

The telescopic feet (12) of the double ladder which are longitudinally displaceable individually in hollow-section spars (10) have longitudinal slots (16), through which there engages a clamping device (14) extending through mutually opposite walls of the spars. By means of a clamping mechanism which is simple to actuate, the inner walls of the spars are pressed against the outer walls of the telescopic feet. The frictional connection guarantees an absolutely firm fixture. <IMAGE>

Description

The present invention relates to an inverted V-shaped stepladder, with four bars, two of which are each connected in one plane with a hinge and with the remaining bars in a spaced parallel plane with any number of rungs, at least part of the spars can be individually extended by means of these telescopic feet and can be locked in any position by means of a tensioning device.

When using stepladders, situations often arise in which the spar lengths have to be adjusted downwards to different height conditions in order to achieve a safe and stable installation of the ladder. A typical example is a spiral or arched staircase on which a painter's ladder has to be repositioned again and again in rapidly changing positions. In this case or in a similar manner, the support surface of a ladder set up in this way can be distributed over four different levels. The different levels require that each spar be set to a different length, and the extent of the differences can be arbitrary.

A reversed V-shaped step ladder with bars made of wood or metal is known, on the outside of which loose extension slats can be attached as required. These extension brackets can also be attached as wooden telescopic feet to the outside of the bar. It can be fixed in any position by means of clamp-like devices. The attachment and detachment of such fixation devices is extremely cumbersome and time consuming. These are loose files that have to be put together. Since the supplementary parts do not remain firmly attached to the ladder, they are often lost. Two clamps are required for each spar extension. Both have to be screwed tight. One-handed operation is not possible. Safety is not guaranteed, as a clamp that is not fully clamped can cause the corresponding extension to kink.

Also known is an inverted V-shaped step ladder with bars made of hollow metal profile in which telescopic feet are guided. These have holes at intervals through which pins are inserted after the holes have been aligned with holes in the spars. The fixation is also cumbersome here and the telescopic feet can only be extended gradually.

The invention is based on the object of making a step ladder of the generic type available in which the telescopic feet which can be extended into any positions can be easily and securely fixed in the desired position with a single handle.

The ladder according to the invention should also be as light as possible and take up little space.

This object is achieved according to the invention by a stepladder with the features of the characterizing part of claim 1.

Due to the clamping device used in the invention, each telescopic foot can be in any position fix securely in no time.

Preferred developments of the step ladder according to the invention are characterized in the subclaims.

It is advantageous to arrange a short additional ladder which can be hooked onto the stepladder and which extends the rungs downwards when the telescopic feet are extended.

It is particularly advantageous to replace several additional conductors if necessary, i.e. When extending the ladder, provide extendable rungs that make it easier to climb the ladder even when the telescopic feet are extended and do not have to be carried as an additional part of the ladder.

Further details, advantages and features of the step ladder according to the invention result from the following description of exemplary embodiments shown in the drawing.

• Fig. 1 eine perspektivische Ansicht der bevorzugten Ausführungsform der erfindungsgemäßen Stehleiter,
• Fig. 2 eine auseinandergezogene Darstellung der bevorzugten Ausführungsform der bei der Erfindung verwendeten Spannvorrichtung in Perspektive,
• Fig. 3 eine seitliche Schnittansicht der Spannvorrichtung nach Fig. 2 im Einsatz,
• Fig. 4 eine alternative Ausführungsform der Spannvorrichtung in Seitenschnittansicht und
• Fig. 5 eine Draufsicht einer Zusatzleiter wie sie insbesondere bei der erfindungsgemäßen Stehleiter Verwendung finden kann,
• Fig. 6 eine Leiter mit Teleskopfüßen und in diesen geführten Zusatz Sprossen im Zustand vor dem Einfahren der Teleskopfüße,
• Fig. 7 eine seitliche Führung einer Sprosse in einem Teleskopfuß und
• Fig. 8 eine Stehleiter mit Teleskopfüßen und in diesen geführten Zusatz Sprossen im besteigbaren Zustand.

Show it:

• 1 is a perspective view of the preferred embodiment of the step ladder according to the invention,
• 2 is an exploded perspective view of the preferred embodiment of the tensioning device used in the invention;
• 3 shows a sectional side view of the tensioning device according to FIG. 2 in use,
• Fig. 4 shows an alternative embodiment of the clamping device in a side sectional view
• 5 shows a plan view of an additional ladder as can be used in particular in the step ladder according to the invention,
• 6 is a ladder with telescopic feet and rungs guided in these in the state before the telescopic feet are retracted,
• Fig. 7 is a lateral guidance of a rung in a telescopic foot and
• Fig. 8 is a stepladder with telescopic feet and in this led additional rungs in the mountable state.

According to FIG. 1, the stepladder has bars 10, from which telescopic feet 12 can be extended into any positions and are fixed in a selected position by means of a clamping device 14.

In the preferred embodiment, the spars 10 consist of profile tubes, preferably tubes with a rectangular cross section made of aluminum. The telescopic feet 12 are profile tubes preferably made of aluminum with an outer cross section that matches the inner cross section of the profile tubes of the spars 10 in such a way that the telescopic feet 12 are easily guided in the spars 10. In the preferred embodiment, a rectangular cross section is selected as the cross section, although other profiles could also be used.

The telescopic feet 12 have longitudinal slots 16 in two opposite walls, which in the exemplary embodiment are formed in the side walls of the telescopic feet 12.

A tensioning device 14 extends through openings 22, 24 (FIG. 3) through the side walls of the bars 10 and the slots 16 in the telescopic feet 12. In the released state, the tensioning device allows the telescopic feet 12 to be moved freely, while in the tensioned state it fixes the set position of the telescopic feet 12 clearly and immovably. The tensioning device 14 is mounted at such a small distance from the lower opening of the bars 10; that the telescopic feet 12 still have sufficient hold in the rooms 10 when extended.

Figure 2 shows an embodiment of the clamping device 14 in detail. A screw 30 is passed through the openings 22 and 24 (see also FIG. 3) through the spar 10 and the slot 16 in the telescopic foot 12 guided therein. The screw 30 has a head 32, the end face pointing towards the opening 24 is provided with a rotation lock, which can have, for example, the shape of a square 34 which fits into the correspondingly square opening 24.

The following elements are lined up on the side opposite the head 32 of the screw 30: a flexible disk 36, preferably made of rubber or plastic, a spring plate 38, preferably made of steel, a washer 40, a spring washer 42 and a further washer 44. This sequence is completed by a handwheel 46 that can be screwed onto the screw 30, preferably made of plastic.

Figure 3 shows that the flexible disc 36 fits exactly into the opening 22. Preferably, the flexible disc 36 is on the side facing the opening 22 of the Spring plate 38 attached, for example glued, whereby the friction-increasing disc 36 automatically lifts off the surface of the telescopic foot 12 in the released state of the clamping device 14. This facilitates the immediate displacement of the telescopic foot and reduces the wear of the flexible disk 36, while on the other hand, an increased frictional pressure is exerted on the telescopic foot 12 in the tensioned state. One-handed operation is also made easier.

The spring plate 38 is fastened to the side of the opening 22 and at a distance therefrom with the interposition of washers 48 on the outside of the spar 10, for example riveted or screwed, for example with rivets 50 (FIG. 2). In this way, the spring plate 38 is held in the released state of the tensioning device at a distance corresponding to the thickness of the washers 48 from the outer surface of the spar 10, whereby the already mentioned removal of the flexible disk 36 from the telescopic base 12 is achieved.

The spring ring 42 ensures that in the tensioned state of the tensioning device 14 a correspondingly large force the spring plate 38 with the flexible disk 36 below is pressed against the 'outer wall of the spar 12, while on the other hand the screw head 32 the wall of the spar 10 against the other outer surface of the telescopic foot 12 presses.

Although the tensioning device 14 according to FIGS. 2 and 3 has proven to be particularly advantageous, other tensioning devices working on the same principle are possible, which secure the telescopic feet 12 in the bars 10 by pressing the walls of the bar 10 together and pressing them against the walls of the telescope ensure foot 12.

FIG. 4 shows, for example, a modification of the tensioning device 14 from FIGS. 2 and 3, a dome-shaped compression spring 52, under the action of the handwheel 46, causing the compression described above.

Another possibility of the tensioning device would be the use of a tip lever or snap lock, as is usual with ski bindings or the like.

In another embodiment of the stepladder according to FIG. 1, the slots and the direction of the tensioning device could be offset by 90 degrees. It would also be possible to form the longitudinal slots in the spars and to guide the telescopic feet with a C-shaped cross section over the spars. Furthermore, the telescopic feet 12 of the embodiment according to FIG. 1 could also consist of two strips arranged parallel to one another with a slot in between, as indicated in FIG. 2 at position 56.

When the handwheel 46 is closed, the inner walls of the spar 10 are pressed against the outer walls of the telescopic foot 12. The resulting frictional engagement guarantees an absolutely immovable fixation. This is supported by the additional friction between the flexible disk 36 and the outer wall of the telescopic foot 12. When the handwheel 46 is released, the spring plate 38 lifts the flexible disk 36 from the telescopic foot 12.

The arrangement of an additional ladder such as is of general inventive importance for stepladders with telescopic feet and in particular for the stepladder according to the invention it emerges from Figure 5. The additional ladder has bars 60 and a few rungs 68. Hooks 70 are provided at the upper end of the bars 60 and can be hooked into rungs 18 (see also FIG. 1) of the stepladder. At the lower end of the additional conductor, a strip 72 is fastened to the spars with a length which corresponds to the distance between the outer edges of the spars 10. The strip 72 can also serve as the bottom rung. At the opposite ends it can have bends 74 which can overlap the spars 10 or the telescopic feet 12. The rung spacing and the rung width preferably correspond to those of the stepladder. When the telescopic feet are retracted, the additional ladder is hung on one of the upper rungs, while when the telescopic feet are extended, the additional ladder is hung on a rung 18 so that a normal rung ladder results in combination with the stepladder.

Another option for filling the rung gap that occurs when the telescopic part of the stepladder is extended is to guide rungs in a slot of removable telescopic feet, which are connected to one another by flexible connecting elements, for example chains, and the uppermost rung in turn by a flexible connecting element the fixed part of the ladder. The bottom rung, which is to be extended, is fixed to the fixed part of the ladder at any distance from the bottom rung of the ladder with the aid of a further flexible connecting element and a hooking element.

FIG. 6 shows a ladder which has bars 10, from which telescopic feet 12 can be extended in any position and are fixed in a selected position by means of a known tensioning device 14.

The telescopic feet 12 also have longitudinal slots 16 in two opposite walls, which in the exemplary embodiment are formed in the side walls of the telescopic feet.

The tensioning devices 14 are inserted through the longitudinal slots 16 and ensure that the telescopic feet 12 are securely fixed in a known manner in any extended or retracted position. Furthermore, in the longitudinal slots 16, the rungs 18 additionally required for climbing the ladder 18 when the telescopic feet 12 are extended.

FIG. 7 shows a detail of the rung guide in a longitudinal slot 16. In the present exemplary embodiment, the rung 18 has a rectangular cross section. It preferably consists of an aluminum hollow profile. The narrow side of the profile is somewhat smaller than the width of the longitudinal slot 16, so that the rung 18 is easy to move in the longitudinal slot 16. By means of a bolt 76, the rung 18 is secured against slipping out of the guide 16 laterally. This bolt 76 can consist of a simple steel pin which is inserted through corresponding holes in the hollow profile.

In this way, as many additional rungs 18 are guided in the slots 16 of the telescopic feet 12 as are necessary to climb the extended ladder part. In the illustrated embodiment, these are three rungs. The rungs are connected to one another with chains 78. The chains 78 have a length that corresponds to the distance between the rungs. There is an additional rung on the lowest sliding rung Chain 80 attached. This is suitable for fixing the rung 18 in a pushed-together state, as shown in FIG. 1, by hanging it in a hook 82. The hook 82 is embedded in the lowest fixed rung 84 of the ladder.

FIG. 8 shows a step ladder, in which the rungs 18 are no longer fixed in a closely adjacent position by the chain 80. Rather, they are positioned by the chains 78 at a distance which corresponds to that of the fixed rungs. This makes the ladder easy to climb. Instead of chains 78 and 82, which are used in the present exemplary embodiment, other connecting elements that can only be subjected to tension, such as e.g. Ropes, find application.

Claims (13)

1. Conversely, a V-shaped stepladder with four spars connected to each other either with a joint or with any number of rungs, at least some of the spars being individually extendable by telescopic feet guided on them and being fixable in any position by means of a tensioning device,
characterized ,
that the spars (10) are designed as a hollow metal profile, that the telescopic feet (12) are guided in the hollow profile and have a corresponding cross-sectional profile, that in the telescopic feet (12) longitudinal slots (16) are formed and that the clamping device (14) through two opposite walls of each spar (10) and the longitudinal slot (16) of the telescopic foot (12) which can be guided through it and a clamping mechanism (FIGS. 2 to 4) which can be actuated by a simple handle for producing a securely fixing frictional connection between the spar (10) and telescopic foot (12). 2. stepladder according to claim 1,
characterized ,
that the clamping device (14) has a rotationally secured screw (30), on the opposite end of which a manually screwable member (46) is placed with the interposition of a resilient arrangement (36 to 42). 3. step ladder according to claim 2,
characterized
that the spring arrangement (36 to 42) has a compression spring (42; 52). 4. step ladder according to claim 2 or 3,
characterized
that the spring arrangement (36 to 42) has a spring plate (38) which is fixed on one side at a lateral distance from an opening (22) in the wall of the spar (10) and at a slight distance parallel to this and that the spring plate (38) on the side facing the opening (22) carries a flexible disc (36) which fits into the opening (22) and has a thickness which is greater than the wall thickness of the bar (10). 5. step ladder according to claim 4,
characterized
that the spring arrangement contains the following elements in the order given: the flexible disc (36), the spring plate (38), a washer (40), the compression spring (42) and optionally a washer (44) which is in contact with the manually operable member (46). 6. step ladder according to claim 2,
characterized ,
that the compression spring is a dome-shaped compression spring (52). 7. stepladder according to one of the preceding claims,
characterized ,
that the clamping device (14) at a distance from the lower end of the spar (10) is arranged. 8. stepladder, in particular according to one of the preceding claims,
characterized,
that a relatively short additional conductor is arranged, which can be attached by means of connecting members (70) arranged on the upper end of their bars (60) to different rungs (18) of the stepladder and which has a transverse bar (72) at its lower end which extends over the opposite spars (10) of the stepladder extends. 9. stepladder, in particular according to one of the preceding claims,
characterized ,
that rungs (18) are guided in a slot (16) by telescopic feet (12) which are connected to one another with flexible connecting elements (78) and the uppermost rung is in turn connected to the fixed part of the ladder by flexible connecting elements (78), and the lowermost rung can be held at any distance from the lowest rung of the ladder (84) with the aid of a further flexible connecting element (80) and a hooking element (82) on the fixed part of the ladder. 10. stepladder according to claim 9,
characterized ,
that the maximum distance between the two movable rungs (18) which can be predetermined by the connecting elements (78) corresponds to the rung distance of the fixed rungs of the ladder. 11. step ladder according to claim 9 or 10,
characterized ,
that the connecting elements (78, 80) are chains. 12. step ladder according to claim 9, 10 or 11,
characterized ,
that the movable rungs (18) are rectangular aluminum hollow profiles, the narrow sides of which are somewhat smaller than the width of the longitudinal slots (16). 13. step ladder according to claim 9, 10, 11 or 12,
characterized ,
that the ends of the movable rungs (18) protrude beyond the telescopic feet (16) and they are secured by means of bolts (76) from slipping out laterally.

Images