DE4021937C1 - Load distributing platform for groove support legs - has continuous parallel struts with several pressure or tensile supports in between - Google Patents

Abstract

The load distribution platform for mobile or tower cranes consist of an integral top plate (22), a sectional base plate (10), up and struts (12) between the base and top plates. - The struts extend over the whole width of the bottom plate and are mutually parallel. Supports (16) are welded between the struts to take up compression and tensile loads at right angles to the struts.

Description

The invention relates to a load-distributing platform for the support feet of cranes, especially vehicle or tower cranes.

When using cranes, especially for vehicle or tower cranes, this results among other things Problem of supporting the crane. The crane points to this several (usually four) support feet. The support feet are essentially designed as plates that lower to the ground using hydraulic presses are cash. The plates have a relatively small base bearing surface so that it can withstand loads that depending on the design of the crane, a weight of up to 190 t per support leg due to the high Press pressure into the ground. To the furthest going to avoid being flat on the ground  forms placed on which the plates are lowered. Such a platform consists of lying side by side the double-T beams, which are welded together. The double T-beams take in the direction of their length extension transverse forces (in the following longitudinal forces called) reliably. The in to the carrier extension of transverse forces acting in the vertical direction however, are not reliably recorded. At the like loads there is a risk of "tipping over" the double-T beam, what of the execution of the sweat connections depends. Furthermore, in the direction in which the double-T beams are strung together (i.e. in the direction transverse to the longitudinal direction of the beam), hardly any Load distribution. The total vertical load is only taken up by those double-T beams on which the support foot plate rests. Finally stand out the known platforms through a relatively high Ge important because of the static described above Problems of relatively large steel beams are used have to.

From DE 72 33 206 U1, from which the claim 1 is a light metal jack with a bottom part and a cover part known. Both rounded off th corners provided, essentially square parts are with themselves radially from the center to the outer edges extending integrally molded ribs, those in the assembled state of the support frame engage and over which the two parts against each other who are supported. The design and manufacture both the lid and the bottom part are relative complex. The support point at which the support foot is located of the crane is located in the center from which extend the ribs and in which the cover part  a recess to accommodate the support leg is. The cover part has a drop on all sides on the top, which is why the crane's support leg only be let into the recess can. This is after in confined spaces part.

The invention has for its object a load distributing platform for the support feet of cranes, in particular to create mobile or tower cranes, which has a simple construction and the a reliable load distribution with shear force is given in all directions.

To solve this problem, the invention provides beat between the (not necessarily a in part, that is to say also in several parts ten) base plate and the cover plate several to each other to provide parallel, continuous webs and to open take from substantially perpendicular to the extension the transverse forces acting between the webs arrange several support elements that occur when they occur from shear forces pressure and / or tensile loads are set and thus the webs hal in their position ten.

The webs of the platform according to the invention run parallel to each other and extend across the ge total width or length of the two plates (by walking bridges). Between the webs are under pressure or Train resilient support elements arranged with at least one web and one of the two parallel ones Slabs, advantageously with adjacent webs are connected. The cover plate preferably consists of  a one-piece steel plate. At the bottom plate can also be a one-piece or a Act lumpy steel plate. In an advantageous further education of the invention is the bottom plate of several strip-shaped plate parts assembled, the Space between those facing away from the cover plate Cover the ends of the webs and move towards the Extend webs (also a multi-part base plate is intended in the context of this invention with the word floor plate can be called). For the individual floor plate strip is advantageously so-called Wide flat steel material used. The width of the The base plate strip corresponds to the spacing of the bars chosen, the longitudinal edges of the flat steel Material with the edges of the webs and the support elements are welded. The webs are advantageously one-piece  narrow upright or under another win plate strips running to the cover plate, ie also about flat steel material.

The support elements, depending on the type of their training and Connection with the webs "on train or push" be be used if perpendicular to the longitudinal extent the webs, i.e. in the direction of the arrangement of the webs, transverse forces occur, take transverse loads on and thus hold the webs in their position, so that the plate in the transverse direction, i.e. transverse to the (longitudinal) Extension of the webs acts as a lattice girder. In the direction perpendicular to the web longitudinal direction behaves the platform is like a floor or cover plate wider the webs and the supporting elements Truss girder, which act in its longitudinal extension the forces (transverse forces in relation to the extension of the Webs) also reliably withstands them takes. The platen acts in the longitudinal extension of the webs shaped like a box girder, which holds the bending moments in Reliably records and distributes lengthways. The The platform according to the invention therefore behaves statically like a platform stretched crosswise. Through the Truss training will save 30% in weight achieved compared to conventional platforms.

The platform according to the invention can optionally have four or three-sided, but also only at certain points be stored. In all of these cases there is a to reliable distribution and inclusion of the longitudinal and transverse forces through the platform. It is extremely rigid and therefore takes up the at point storage occurring bending moments over their entire area casually on. The different storage options,  where the platform always performs its function of the load Distribution maintains are therefore particularly important partial, since no detailed studies of the Conditions in the area of the earth on which the Platform rests, must be turned on. About spans the platform lying on the ground for example a pipe running in the ground, the soil on both sides of the Pipe off. Are in the pipeline extension no outriggers required as the drawbar load is over the platform in perpendicular to the pipe run Direction is distributed where the platform is on solid Surface rests. Even if an edge area of the The tube protrudes from the platform above the pipeline cable with support loads acting on the platform not damaged since the platform in this case behaves like a continuous platform. The use of the load-sharing platform according to the invention as Ceiling or support plate is crosswise because of the tensioned construction also possible.

The shape of the plates is basically arbitrary bar. Generally the bottom and top plates are rectangular, the length of the rectangle edges are preferably 2 m or 4 m. Right The webs preferably run in angular plates parallel to the edges. Basically, you can also round floor and ceiling panels can be used.

The support elements are each advantageous arranged between two adjacent webs, being the upper end of the one facing the cover plate Web with the lower end facing the base plate connect the adjacent bridge (diagonal or dia  gonal support elements). The support elements cont barter pairs of webs can be parallel to each other or run opposite to each other. Depending on the direction in which the transverse forces act is the Support elements made of either compressive or tensile loads set. The support elements are preferably designed as (Dia gonal-) rods, each with several rods are arranged between two adjacent webs and all webs perpendicular to the floor or cover plate run.

In an advantageous development of the invention is also provided that the support elements than themselves over the Length of the webs extending support plates formed are sloping between two neighboring ones Bridges are arranged. The top ends of the webs with the lower ends of the adjacent bridges connecting support plates give the platform a great stability under shear loads. Also the Support plates are advantageously made as strips formed and made of wide flat steel material.

In general it can be said that the direction of inclination, Strength and design of the support elements accordingly static requirements. For train Load-bearing support elements can do less be highly trained than for pressure loads put support elements. The formation of the support elements as rods compared to training as continuous Plates the advantage of lower weight.

Are the support elements as continuous support plates formed, the length of which is equal to that of the webs is, according to a further advantageous further  Education of the invention provided that the webs on two opposite edges of the bottom and the deck plate arranged vertically and the remaining webs and the support plates each in pairs against each other are aimed. In this embodiment of the invention is the number of the same platform dimensions Bridges and support plates acting as support elements less than in the case where the webs are perpendicular to the Bottom and top plate run. This leads to itself advantageous handling of the platform Weight savings.

A first and a second are advantageous Group of parallel to each other Support elements provided, the support elements of the first group opposite to those of the second Group are aligned. In this training the Invention run - when looking at the platform of above - all in one half of the platform sensitive support elements parallel to each other, are each but opposite to the support elements of the others Half of the platform aimed, including the support elements in this other half again to run parallel to each other. In side view of the The support elements on this white platform terbildung the invention so herringbone. These Arrangement of the advantageously designed as rods Deten support elements has the advantage that Querbe loads in both directions a group of Rods is under pressure or tensile load and thus the cross absorbs strength. Depending on which plate the Platform according to the invention rests on the floor the group of the bars absorbing the transverse forces or tensile. Bars designed for tensile forces can  be less strong, which is why with a flat shape in which the rods are subjected to tensile loads precautions should be taken that it make it easier for the operator to use the "rich "page on the floor a further advantageous further development of the Erfin provided that the surface of one of the plates, namely either the top or bottom plate, professional is. The profiled surface should be correct ter application of the platform must point upwards. This also has the advantage that these waiters area that may be walked on, non-slip is.

The webs with the support elements are advantageously and the top and bottom plates are welded. Around ver the cover plate with the already with the base plate to be able to connect welded webs Cover plate in the area of contact with the Webs or the support elements openings (holes, Slots or the like.) Provided. The hole edges can now welded to the edge surfaces of the webs from above with which the connection of the cover plate with the remaining part of the platform by welding on convenient Kind is made possible. If the base plate is in one piece is formed, it should also have openings, about welding to the webs and the support elements to facilitate.

For the distribution of the support foot on the platform load acting next to the two (floor and Deck) plates, the continuous webs and the supports elements with shear forces in both directions and Record bending moments because the platform is in one  Direction as a box girder and in the vertical ver running other direction than lattice or truss acts sluggish.

In the following, the figures are used to implement the figures games of the invention explained in more detail. In detail demonstrate:

Fig. 1 is an exploded perspective view of a platform according to a first embodiment of the invention,

Fig. 2 is a perspective view of a flat form according to a second embodiment of the invention,

Fig. 3 is a perspective view of a flat form according to a third embodiment of the invention,

Fig. 4 is a plan view of the top plate of a platform, which is used in one of the platforms shown in FIGS. 1 to 3, and

Fig. 5 is a sectional view taken along the line VV of Fig. 4.

In Fig. 1 a first embodiment of the load-distributing platform according to the invention is shown in perspective in an exploded view. The platform has a rectangular base plate 10 , to which a plurality of upstandingly arranged webs 12 are welded. The webs 12 are evenly distributed over the length of the bottom plate 10 and run parallel to one another and parallel to the two opposite one another, the width of the bottom plate 10 determining transverse edges 14 of the bottom plate 10 . The webs 12 have the shape of rectangular narrow plates strip (flat steel), which are arranged upright, that is to say with one of their longitudinal edges on the platform 10 . Between each two adjacent webs 12 , a plurality of support elements in the form of rods 16 are arranged, the two ends of which are connected to the two adjacent webs 12 . One end of a rod 16 is welded to the lower end 18 (the lower longitudinal edge) of a web 12 , while the other end of this rod 12 is welded to the upper end 20 (the upper longitudinal edge) of the adjacent web 12 ( diagonal bars 16 ). While the lower ends 18 of the webs 12 face the base plate 10 or are welded to it, the upper ends 20 face a one-piece cover plate 22 , to which they are welded if necessary. The more precise design of the cover plate 22 is shown in FIG. 4, which will be discussed later.

The cover plate 22 , the base plate 10 and the webs 12 arranged between them (bolts) and support elements in the form of the rods 16 are shown in FIG. 1 of the better understanding of the construction of the platform because of the exploded view. Of course, all of the parts shown in Fig. 1 are connected (welded) together.

The base plate 10 and cover plate 22 are congruent and have edge lengths of approximately 2 m and 4 m. The entire platform is made of steel, whereby the thickness of the floor and cover slab as well as that of the webs and that of the diagonal bars are basically chosen according to the structural analysis.

For example, the strength of the floor and the Ceiling panels about 10 mm, while the webs and the Diagonal bars have a thickness of about 8 mm.

As can be seen in FIG. 1 (and also in the other figures to be written later), the base plate 10 consists of a plurality of plate strips 23 which are arranged next to one another at a small distance and which are made of flat steel material. Adjacent plate strips, the width of which is adapted to the distance between two adjacent webs 12 , are welded to one another (see the weld seams 21 in the figures). The plate strips 23 are also connected to the edges of the webs 12 by the weld seams 21 . By welding points or weld seams 19 , the bars 16 are firmly connected to the webs 12 and the base and cover plates 10 and 22 as well as the webs 12 to the base and cover plates 10 and 22 .

As can be seen from FIG. 1, the bars 16 can be divided into two groups, namely a first group A and a second group B. The rods 16 of group A are - when viewing FIG. 1 - in the left half of the platform, while the rods 16 lying in the right half of the platform belong to group B. The bars 16 of both groups extend to the associated base plate edges 14 rising. The rods 16 are thus arranged in the two groups of the type that they connect the lower end 18 of a web 12 with the upper end 20 of the web 12 closer to the edge 14 nen. In the event of transverse forces acting in the direction of the double arrow 24 , the rods 16 are each tension-loaded in a group and thus hold the webs 12 in their position shown in FIG. 1 relative to the plates 10 , 22 . In the direction of the double arrow 25 acting transverse forces (longitudinal forces) are absorbed by the webs 12 .

FIG. 2 shows a further exemplary embodiment of the platform, which largely resembles that according to FIG. 1. As far as possible, the same parts are marked with the same reference numerals as in Fig. 1. The difference of the platforms according to FIGS. 1 and 2 is that instead of the rods 16 in the embodiment according to FIG. 2, support elements are provided which are designed as plates 26 extending across the width of the platform. The plates 26 are arranged or inclined like the bars 16 of FIG. 1 and also connect the upper end 20 of a web 12 to the lower end of the adjacent web 12 closer to the center of the platform. The sloping plates 26 , like the rods 16 of the exemplary embodiment according to FIG. 1, can also be divided into a first and a second group, the alignment of the plates within these groups corresponding to that of the rods 16 of the first exemplary embodiment. The plates 26 are also made of steel and have a thickness of approximately 8 mm.

In Fig. 3, a third embodiment of a platform is shown. This platform has two perpendicular right on the base plate 10 extending webs 12, which extend along the two mutually parallel transverse edges 14 of the bottom plate 10 and welded at the edges 14 with the bottom plate 10 degrees. Between the perpendicular right webs 12 are also arranged across the width of the base plate 12 extending webs 28 which run at an acute angle to the base plate 10 , all the webs 28 being parallel to one another. Between adjacent sloping webs 28 , support elements are arranged, which also run obliquely and in the form of extending across the width of the base plate 10 support plates 30 (diagonal plates) made of flat steel material. The support plates 30 connect the upper end 20 of the inclined webs 28 facing the cover plate 22 to the lower ends 18 of the respective adjacent webs 28 facing the base plate 10 . In this way, pairs of webs 28 and support plates 30 are formed , which are assembled in a V-shape. In this exemplary embodiment, the webs 28 and the support plates 30 are equally involved in receiving transverse forces acting in the direction of the double arrow 24 as well as in the direction of the double arrow 25 acting "longitudinal forces". The edge webs 12 , which run perpendicular to the base plate 10 , can only absorb forces in the direction of the double arrow 26 .

In Fig. 4, the cover plate 22 is shown, which is used in example in the embodiment of FIG. 1. The rectangular cover plate 22 is provided with a plurality of openings arranged in rows in the form of elongated holes 32 (or slots), which are arranged in those strip areas of the plate 22 in which the upper ends 20 (or rather the upper longitudinal edges) of the webs 12 rest on the underside of the cover plate 22 . In plan view of the platform of FIG. 4 thus through the upper longitudinal edges of the webs 12 are bar view through the elongated holes 32. Due to the arrangement of elongated holes 32 at the locations of the cover plate 22 described above, this can be welded to the remaining part of the platform in a particularly simple manner by the edges of the holes 32 being welded "from above" to the upper longitudinal edges of the webs, which is shown in Fig. 5. The surface of the cover plate 22 can be profiled, which is indicated at 34 . Because of the profiling 34 , the crane operator recognizes the surface with which the platform is to be laid on the ground, so that the bars 16 are subjected to tensile stresses when transverse forces occur. If the platform is placed on the ground in such a way that the profiled surface faces the surface of the ground, the rods 16 of the platform according to FIG. 1 are subjected to pressure stresses when transverse forces occur, for which they may not be designed, since tension rods are less strong can be formed out as pressure rods.

Claims (13)

1. Load-distributing platform for the support feet of cranes, in particular vehicle or tower cranes, with

• - a base plate ( 30 ),
• - A one-piece cover plate ( 22 ), and
• - a plurality of webs ( 12 ) between the base plate ( 10 ) and the cover plate ( 22 ),

characterized,

• - That the webs ( 12 ) run continuously and parallel to each other and
• - That between the webs ( 12 ) a plurality of pressure and / or tensile stresses supporting elements ( 16 , 26 , 30 ) are arranged for receiving transverse forces acting substantially perpendicular to the extension of the webs ( 12 ).

2. Platform according to claim 1, characterized in that the support elements ( 16 , 26 , 30 ) are each arranged between two adjacent webs ( 12 ), wherein they the top plate ( 22 ) facing the upper end ( 20 ) of a web ( 12th ) connect to the bottom plate ( 10 ) facing the lower end ( 18 ) of the adjacent web ( 12 ). 3. Platform according to claim 2, characterized in that the supporting elements are designed as rods ( 16 ), wherein a plurality of rods ( 16 ) are arranged between two adjacent webs ( 12 ). 4. Platform according to claim 1 or 2, characterized in that the webs ( 12 ) on two opposite edges ( 14 ) of the bottom and the cover plate are arranged vertically and that the other webs ( 12 ) and the support elements ( 16th , 26 , 30 ) are directed towards each other in pairs. 5. Platform according to one of claims 1, 2 or 4, characterized in that the support elements are designed as support plates ( 26 , 30 ) extending over the length of the webs ( 12 ), which lie obliquely between two adjacent webs ( 12 ) are arranged. 6. Platform according to one of claims 1 to 5, characterized in that all the webs ( 12 ) perpendicular to the base plate ( 10 ) and to the cover plate ( 22 ). 7. Platform according to one of claims 1 to 6, characterized in that a first and a second group (A, B) of parallel to each other extending support elements ( 26 , 30 ) is provided, the support elements ( 26 , 30 ) the first group (A) are oriented opposite to those of the second group (B). 8. Platform according to one of claims 1 to 7, characterized in that the webs ( 12 ), the support elements ( 16 , 26 , 30 ) and the top and bottom plates ( 22 ; 10 ) are welded together. 9. Platform according to one of claims 1 to 8, characterized in that the cover plate ( 22 ) in the region of the contact surfaces with the webs ( 12 ) and the support elements ( 16 , 26 , 30 ) is provided with openings ( 32 ). 10. Platform according to one of claims 1 to 9, characterized in that the base plate ( 10 ) is composed of a plurality of individual strip-shaped plate parts ( 23 ) connecting the webs ( 12 ) to one another. 11. Platform according to claim 10, characterized in that the strip-shaped plate parts ( 23 ) with each other and with the webs ( 12 ) and the support elements ( 16 , 26 , 30 ) are welded. 12. Platform according to one of claims 1 to 11, characterized in that the surface of the top or bottom plate ( 22 , 10 ) is profiled.