DE19802741A1 - Ground support for ladder or frame structure - Google Patents

Abstract

The support structure, for ladders and frames, has an expanded side rail structure. An additional support foot (16) is fitted to at least one side rail (1) at a triangular linkage (2-8) with height adjustment. The linkage supports (2,3) along the side rail have a stepless fixing through a clamping clip or a clamp system (15).

Description

The invention relates to a support device on conductors or frames, hereinafter for simplicity's sake as Ladder rack named, with a foot extension that adapts to a different location by the support height, support width and the Support angle can be set, or the entire Vorrich device can be folded to save space.

The known support devices on ladder frames are usually either rigidly attached as a foot extension or can only make a height difference without widening balance. Solutions that combine both Disadvantage that it is limited in the possibility of adjustment or the handling is too cumbersome. Another one The disadvantage is the bulky design of such known Solutions for what to do with adjustment, transport and storage keeping a ladder rack particularly disadvantageous works.

Support especially for leaning ladders is increasing with the introduction of aluminum ladders because the accidents caused by the slides on the bars Jetty (to the side) or on the bar foot (to the rear) increase. One of the main focal points of the accident is the lateral slide people at the landing stage while crossing one Person from the rung on a higher work place or vice versa, but also if the relevant Person standing above bends too far to the side, e.g. B. at Tree work. This is due to the relatively low static friction the spars at the upper contact point for light metal spars justify. Another focus of the accident is the Wegrut of the spar feet to the rear when the open or descending person is in the upper area. Here too  the light metal spar is more dangerous because in turn the Stiction at the jetty (as justified) less and which is used by the industry to secure foot supports (mostly plastic inserts) are insufficient. Light alloy spars have z. B. compared to wooden spars another part by going up or down the spars bounce and so through the constant small angle Change at the mooring point and spar foot the transition of detention Favor friction to sliding friction. It is similar with racks that are ajar, such as. B. from smaller portable work platforms.

The object of the invention is to ensure the possible use Possibilities of the ladder frame according to the given in practice and easy to use and perform quickly by the ladder rack beforehand kept aligned and adjusted the support at the same time can be.

The object is achieved in that an additional support leg is attached to at least one spar is adjustable in height to the Terrain shape can be adjusted, regardless of whether that Terrain has an increase or decrease. With the Solution to fix the lower joint base firmly and the upper joint base is variably adjustable in length but on the one hand, training to be ascertainable becomes a large part of the adaptation options to the site and on the other hand, the handling is improved so that the adjustment possibility ergonomically favorable at hand height of a standing Person lies. Another advantage of this invention is that despite the large support arm, the device z. B. by pushing up the upper joint support quickly and can be folded along the spar to save space. In order to can also cross the ladder on one side close to one standing wall or other obstacle, without having to change or remove the support.

Another object is achieved according to the invention in that that the hinge struts or their articulation points in the area Swivel the articulation points on the side bar inwards are trained bar. So that the supportive effect not only to the side, but also to slip away the spars to the rear are largely avoided. With this two-dimensional adjustment option achieves this Ladder rack is stable in almost any terrain unit attached to a lashed or fixed conductor Frame is equated with the decisive advantage that the ladder frame is variable in its placement possibility remains and the support or down from the ground can be reached from without having to climb up first  they z. B. lashing down, which is rarely done in practice will and is not always possible.

In terms of better and faster handling, this will be solved according to the invention in that preferably the upper joint support is infinitely variable and self-locking is formed and with one hand on the one hand Self-locking released and the joint base can be moved can. The stepless adjustment is made by the as sliding shoe-trained joint base on the spar enables the guide encompasses the spar, but the required recesses the width of a strut or rung. The Self-locking in the support direction guaranteed by the Supporting force transmission on the one hand a stepless and on on the other hand, a reliable locking, since the clamp effect increases according to the support force. With the intended spring, which is in the direction of clamping voltage , two variants can be used as required be enough that either by higher spring tension independent sliding of the joint base downwards and thus an unwanted falling is avoided, or with a corresponding reduction in the spring force desired, independent slipping through the heavy By virtue of the linkage, what z. B. become advantageous can, if the opposite support point at Climbing z. B. a ladder unexpectedly something in the Has pushed the ground to make an unsafe game to compensate independently between the bases.

The combination of the solutions according to the invention is fulfilled another task by making optimal use of the handling is because the ladder frame with raised support can be adapted to the terrain beforehand. With the ladder frame is to be held with one hand and with the the other hand can operate the support (lowered and be pivoted). The second required if necessary Support on the opposite side is appropriate adjustable without play. Thus the ladder rack is behind alignment by a standing person with only two Handles can be supported two-dimensionally on both sides, the same Which terrain shape is valid, whether sloping or up increasing and what obstacles are present.

Another advantage results from the invention Solution through the lower clamp shoe Joint base, similar to the upper joint base. Of the e.g. B. releasable lower with clamping screws or clamping levers The articulation base can be pushed up continuously and in addition to changing the outrigger width (according to the radius of the lower hinge strut) one additional advantage that the whole support unit is higher  can be put what z. B. is required if that Ladder rack immediately next to a higher intermediate platform must be leaned. After ver the lower joint base is supported then on the intermediate platform and the further support setting is possible as previously described.

For larger ladder racks, the Ab support by means of telescopic changes to the joint strive also usable and achieve more Advantages by having a longer ladder frame against this Deflection is supported and therefore three-dimensional is adjustable, which is also here with existing obstacles of great use at the location of the ladder rack can be. In this version, the ladder frame can also be used free-standing.

Finally, the embodiment of the invention Joint bases using separate, symmetrical sides plates and corresponding spacers in the fasteners suitable for this support device all common spars, preferably with aluminum spars Rectangular profiles to be able to retrofit. Or it will on that Ladder frame attached to a separate guide rod.

Further advantages and details are in the following Description and the drawings can be seen before preferred embodiments and adjustment options as Show example.

They represent:

Fig. 1 is a front view of a ladder frame with the support device according to the invention, wherein the right support from the normal position and the left shows a device raised on a paragraph.

Fig. 2 shows another adjustment of this support device, the right support in a negative position on a lower ground and the left support completely folded up next to an obstacle (wall).

Fig. 3 shows the side inside view of the spar and the strut or rung with the joint support according to the invention.

Fig. 4 is a side view of the ladder frame with the upper joint support according to the invention without a front cover plate.

Fig. 5 shows the side view of the ladder frame with the support device according to the invention in the inwardly pivoted position and telescopically extended struts, as well as the thrust force geometry of the ladder frame when loaded by a person without support.

Fig. 6 shows the side view of the variant according to the invention as a ball joint with operation on the support on the upper joint support.

Fig. 7 shows the side view of the variant according to the invention as a universal joint using the example of the lower joint support.

Fig. 8 shows the front view of the variant according to the invention with a side-mounted guide rod and the modified operating lever for self-locking, as well as the tensioning lever for the lower joint support point.

Fig. 9 shows the side view of the variant according to the invention with an inward support device.

The support shown in Fig. 1 to 4 consists in its basic form for each side of a spar from an articulated triangle with the articulated struts 4 and 5 , as well as the articulated supports 2 and 3 and the support leg 16 (the opposite, mirror-image parts are identified with xx ' records). The articulated struts 4 and 5 are connected via rotatable bearing bolts 6 , 7 and 8 on the one hand to the support leg 16 and on the other hand to the longitudinally displaceable joint 2 and 3 on the spar 1 to form an articulated triangle. The longitudinal displaceability of the articulated supports 2 and 3 will be sufficient if two symmetrical plates 2 and 2 '( FIG. 3) or 3 and 3 ' (not shown) enclose the spar 1 , with two guide lugs 2 a and 2 on the spar inner side 2 a ', or 3 a and 3 a' are present, the clear distance is slightly larger than the rung width 1 a ( Fig. 3). The screw connection 15 on the one hand holds the plates 2 , 2 'or 3 , 3 ' together and on the other hand represents the opposite guide to the spar 1. By means of the spacers (eg tubes, washers) 14 , the joint supports 2 and 3 of the spar thickness can can be adjusted both in thickness and in width. The length of the spacer parts 14 determines the spar thickness and the lateral displacement on the screw connection 15 (eg eccentrically mounted) the spar width, which at the same time includes an adjustment of the guide.

Furthermore, the length of the spacers 14 determines either the clamping or sliding action of the articulated supports 2 or 3 on the spar 1 . In the example shown in the figures, the lower articulated support 3 is clamped on the spar 1 and is thus fixed in place, and the upper articulated support 2 is freely movable in the longitudinal direction or adjustable via an automatic.

Fig. 4 shows such an automatic of the adjustable support. The articulated strut 4 is rotatably mounted on the intermediate lever 11 via a bolt 8 , which in turn is rotatably mounted on the bolt 9 in the articulated support 2 . Due to the correspondingly offset mounting of the bolts 8 and 9 at a distance h and the clamping bracket 12 fixedly attached to the intermediate lever 11 , an increasing self-locking of the articulated support 2 arises on the spar 1 , the stronger the pressure builds up from the supporting articulated strut 4 .

The spring 13, which acts on the clamping bracket 12, avoids a tilting down of the intermediate lever 11 beyond the dead center of the bearing pin 9 and provides a play-free function of self-locking. It also holds the device in the predetermined position and prevents the support from accidentally sliding down during handling. A conventional possibility of adjusting the spring force (not shown) not only allows the self-locking to be supported, but can also allow the device to slide by the device's own weight if the setting is light, if this is desired. This can e.g. B. be the case when a support presses something during the ascent into the ground and deviates from its ideal position by the ladder frame. The ladder frame can be readjusted from an upper fixed position without having to dismount and the support automatically slips into the new support position due to its own weight. With the handle 10 attached to the intermediate lever 11 , the spring-loaded clamping action can be released by tilting and at the same time the articulated support 2 can be moved both downwards and upwards.

The ladder frame can thus be optimally aligned by a person standing upright, held with one hand and with the free hand each support shape direction can be individually adapted to the terrain conditions quickly, with millimeter accuracy and support (without lateral tilting play), as shown in Fig. 1 and 2 is shown in the most important positions. The additional longitudinal adjustment of the lower hinge bracket 3 by loosening the screw 15 allows a change in height of the entire support device ( Fig. 1 left side), so that the support can also be used on higher platforms or intermediate platforms next to the ladder frame.

The support foot 16 is fixedly attached to the hinge strut 5 at right angles in FIGS . 1 and 2 and on the inside a fold-out mandrel 17 which prevents the support foot from slipping sideways as shown in FIG. 2 on the right support side.

The support foot can also or and be designed as an extension of the articulated strut 4 ( 16 a), which achieves the advantage if the support must be made narrower due to a side obstacle (shown in dashed lines).

With a more frequent adjustment of the lower joint support 3 , a quick-release fastener offers itself, which can be most easily achieved by attaching a toggle or lever 36 , 36 'to the screw connections 15 , as shown in FIGS. 7 and 8.

To Fig. 5, 6 and 7 are shown as alternatives and supplements, in particular the additional adjustment of the supporting device to the inside. Such support on the inside or under the ladder frame is just as important as the lateral one, as the force analysis shows. With a leaned ladder frame, a triangle of forces P _G (weight force of the person), P _A system force), P _L (bar foot force) is created when climbing on. If the person is still down (1st rung), the contact force P _{A is} almost zero. If the person climbs up P _G1 , the contact force P _A (P _A1 ) increases continuously and reaches its maximum in the contact area (P _A2 ) before exceeding it. After the equilibrium of forces Act, the system does not support force P _A only at the contact point A from, but generated in the arbor base other than the supporting force P _St P _Sch thrust that must be intercepted only as frictional force. If you set the frictional force at contact point A to zero, which is almost the case with metal bars (aluminum), the thrust P _Sch at an angle of attack α of approx. 70 ° reaches 1/3 of the person's body weight. If the ladder frame is erroneously flattened, the thrust P _{Sch increases} even higher. This thrust force cannot often be absorbed as friction force on dirty or wet floor (concrete), which is the cause of the accidents caused by ladder racks sliding away, especially when the person is in the upper area or just exceeds. However, as shown in FIG. 5 1 supported the wire frame and to the inside (under the spar) and the support foot 16 almost below the abutment point A (base S) arises no pushing force P _Sch and slipping of the spar to the rear is excluded. This is achieved by the descriptive support device in the articulation points 8 and 6 a further vertical joint, such as. B. receives a ball joint 29 or a universal joint 30-34 with 3 lines of freedom (axes 32 , 33 , 34 ), as shown in Fig. 5 and 6 or in Figs. 5 and 7. The inward swivel angle makes the most sense at approx. 45 °, so that the same support effect is achieved inwards in addition to the lateral support.

Fig. 5 and Fig. 6 shows a supplement with improvement of the support joint adjustment. Instead of the handle 10 , a bow handle 23 is pivotally mounted on the articulated strut 18 and the lever 24 connects the intermediate lever 11 via the linkage 26 and the eyelet connection 27 , 28 . Two bevelled lugs 25 fix the bow handle 23 in a form-fitting manner and avoid an unwanted loosening of the clamp support. With the laying of the handle 10 or 23 on the articulated strut 18 , the supporting device can be swiveled inwards in addition to the height adjustment with one hand after the ladder frame has been previously aligned with the other hand.

Desweitern contains the Fig. 5 nor the telescoping of the articulated struts 18, 19 and 21, 22 with the locking device by a plug connection 20, which is sufficient for the coarse adjustment, as a rule. On the one hand, this enables the adaptation to the terrain and, on the other hand, the spar when the support is pivoted in against deflection when getting on and off, which not only creates uncertainty, but also encourages slipping backwards due to small angular movements in the spar base.

This is also no longer possible with the support device shown. A further particular advantage results from the combination of the support device shown in FIG. 5 that a ladder frame can also be used as a free-standing device in uneven terrain, properly aligned (without side inclination), provided that the top position does not exceed the vertical line of action in the support point s, what with appropriate telescopic availability of the hinge struts 18 , 19 and 21 , 22 is achieved.

The solution shown in FIGS . 7 and 8 is an addition as a separate support device that can be completely attached to a ladder frame. The joint supports 37 and 38 are functionally the same as No. 2 and 3, with the difference that the guide is a separate guide rod 35 which is clamped or screwed to the spar 1 via connecting parts 40 . This has the advantage that no adjustment or adjustment elements are required for the different cross-sections of the spar. The guide rod 35 can exist in cross-section as a round or profiled part (e.g. square or hexagonal). In the case of a round guide rod 35 , the possibility of adjusting the support device in the height axis is infinitely variable. While a profiled guide rod 35 allows a grid-shaped adjustment when opening the clamp or plug connection 40 . This design represents a simplified solution to the spherical shape or universal joint solution shown in FIGS. 5 to 7, which compensates for the additional effort of the guide rod 35 .

In FIGS. 8 and 9, another, simplified handling is shown the operation of the pivot supports 37 and 38 by one hand, the clamping action of the lower hinge bracket 38 by means of a lever 36 via a thread in the counter-plate 3 and 3 ', or a clamping cam (Not shown) is achieved and on the other hand, the manual release of the joint support 37 by the rotationally fixed connection of the lever 10 with the bolt 9 enables. Furthermore, the lever 10 is locked against unintentional loosening by a stop 39 .

The alternative described in FIGS. 8 and 9 can of course be combined with all the advantages of those in the previous FIGS. 1-7, including the telescopic ability of the articulated struts 4 and 5 .

With the solutions of the support device according to the invention on ladder racks is an accurate and safe support Possibility for almost any terrain quickly and safely accessible from the ground. Beyond that, the Mäg given, from a leaned ladder frame free-standing ladder frame with the same mentioned To create characteristics.

The design allows retrofitting to almost everyone commercially available ladder racks, especially those with Rectangular bars.

Through the simple, fast and safe handling, as well of functional reliability in almost all areas of application the risk of accidents is reduced and many previous ones Avoid accidents on ladder racks.

Claims (12)

1. Support device on ladders and frames with a spar widening, characterized in that on at least one spar ( 1 ) an additional support leg ( 16 , 16 a) on a height-adjustable triangle on the spar ( 1 ) ( 2 , 3 , 4 , 5 , 6 , 7 , 8 ) is attached. 2. Support device on ladders and frames according to claim 1, characterized in that the articulated supports ( 2 ) or ( 3 ) along the spar ( 1 ) either via a clamp ( 12 ) or and with a clamp ( 14 , 15 , 36 ) is infinitely fixable. 3. Support device on ladders and frames according to claim 1 and 2, characterized in that the clamping bracket ( 12 ) in the clamping position via a in the bolt ( 9 ) rotatable intermediate lever ( 11 ) at a distance (h) with the hinge strut ( 4 ) ge is flexibly connected. 4. Support device on ladders and frames according to claim 1 to 3, characterized in that on the intermediate lever ( 11 ) or clamping bracket ( 12 ) or bolt ( 9 ) a handle ( 10 ) or ( 23 ) is attached or engages. 5. Support device on ladders and frames according to claim 1 to 4, characterized in that on the intermediate lever ( 11 ) or clamping bracket ( 12 ) a spring ( 13 ) presses the clamping bracket ( 12 ) against the spar ( 1 ). 6. Support device on ladders and frames according to claim 1 and 2, characterized in that the articulated supports ( 2 , 3 ) each of two symmetrical plates ( 2 , 2 '), ( 3 , 3 ') and with respective lugs ( 15 , 15th ') are executed. 7. support device on ladders and frames according to claim 1, 2 and 6, characterized in that the two sym metric plates ( 2 , 2 ') and ( 3 , 3 ') are adapted by spacers ( 14 ) of the spar thickness. 8. Support device on ladders and racks according to claim 7, characterized in that the plate fastening ( 14 , 15 ) at the same time represents the opposite guidance and adjustment of the Ge steering supports ( 2 , 3 ) to the spar ( 1 ). 9. Support device on ladders and frames according to claim 1 and 2, characterized in that the supports on the joint ( 2 ) or ( 3 ) the joints ( 6 , 8 ) as joint eyes or joint balls ( 29 ) or as a universal joint ( 30 , 31 , 32 , 33 , 34 ) are formed. 10. Support device on ladders and frames according to claim 1 and 2, characterized in that the articulated struts ( 4 and 5 ) are telescopic and lockable. 11. Support device on ladders and frames according to claim 1 and 2, characterized in that the articulated supports ( 2 ) and ( 3 ) are guided by a separate guide rod ( 35 ) which is fastened to the outer rail ( 1 ) via connecting elements ( 40 ). 12. Support device on ladders and frames according to claim 11, characterized in that the guide rod ( 35 ) is either round and is firmly connected in the connecting element ( 40 ), or is designed profiled and adjustable in the connecting element ( 40 ) in the longitudinal axis is.