EP0668238B1 - Boom profile - Google Patents

Description

The invention relates to cantilever profiles in the preambles of claims 1 and 3 specified genera. Such boom profiles are from DE-U-92 10 902.0 or known from DE-A-23 17 595.

The telescopic boom has a base and at least one telescopic Part, the cross-sectional profiles of the individual telescopic members mostly in are of the same shape but are of different sizes. At the front end The telescopic boom must be lifted when it is under load. As a result, the boom is subjected to a load as a bending beam, i.e. tensile stresses on the top of the boom and on the underside of the The cantilevers predominate under load.

Telescopic booms predominantly have rectangular profiles, since the rectangular shape is particularly well suited for the transmission of transverse forces between the individual telescopic members and also for absorbing different bending moments.
The demand for weight savings led to particularly thin-walled rectangular profiles, which, however, then no longer proved to be sufficiently resilient. In particular, in the case of thin-walled rectangular profiles, undesirable bulges have occurred on the underside, but also in the central regions of the side sections.

One tried to counter these undesirable bulges by: Reinforcing reinforcement plates on the profile areas that are particularly at risk of buckling welded on. Such reinforcing plates do not only increase this Total weight of the telescopic boom, but also the cross-sectional thickness each telescopic part, so that the requirement, as many telescopic links as possible Integrating installation space, cannot be solved if welded-on reinforcement plates to be used.

The known boom sections of the generic type have semicircular, lower sections or semi-elliptical, lower sections. Have these known boom profiles a fairly good dent resistance in its lower section, but have one comparatively low moment of resistance against bending under load.

From DE-A-2 317 595 cantilever profiles of different cross-sectional shapes are known. Among them is an essentially box-shaped profile with four approximately the same large corner curves in the form of quarter circle segments.

The invention is therefore based on the object of an improved boom profile provide genus mentioned at the beginning, in which the tendency to bulge is reduced and the stiffness especially in the lower and lower lateral profile area is better adapted to the load requirements of a telescopic boom.

This object is achieved by those specified in independent claims 1 and 3 Inventions solved.

Advantageous refinements and preferred embodiments of the invention Boom profiles are specified in the subclaims.

The technical progress achievable with the aid of the invention is primarily due to this see that the sensitivity to buckling of the lower profile area is significantly reduced is because in this area at least one rounded wall section and a flat one Wall section are available. In the at least one circular arc Wall section of the lower profile area can both through Normal stresses as well as shear stresses, which all run in the shell surface, are removed. This component of load transfer, which is in a rounded, bowl-shaped construction is justified known as the "membrane stress state". In principle, such a membrane tension state can be create through continuous transition from the flat profile area into a rounded area without an abrupt transition. Also in the area of overlap between two telegrams are preferably continuous transitions from levels Profile areas provided in rounded profile areas to to reach the membrane tension state.

In addition, the at least one flat wall section with decreasing tendency to bulge the neighboring, rounded section in its lateral extent reduced. As a result, there are more ground points of the lower section of the profile are on the side below, So closer to the bottom corners of an imaginary conventional one Rectangular profile and thus the overall profile additionally a large moment of resistance to bending is own. Furthermore, the boom profile according to the invention allows by the appropriate choice of the included Angle between the rounded, lower profile section and a lateral, oblique fold or between the lateral, oblique bend and the top chord belonging lateral vertical web the vulnerability of the lateral Reduce vertical web against bulging.

In the boom profile according to the invention is the upper section (Top chord) half box-shaped. Through this Design is a particularly advantageous form of the profile in relation to the utilization of the maximum possible section modulus given against bending. Because in the upper profile area the cantilever tension of the boom must prevail in upper, semi-box-shaped profile area does not occur unwanted bulges can be expected.

Further advantages of the boom profile according to the invention result yourself through the possibility of a particularly simple and economical manufacturing. The profile is made by joining of two half-shells, namely the upper chord and lower chord manufactured. The top chord is made in a conventional manner manufactured by folding. The least is with the lower chord a round section formed by polygonal bevelling. The side folds are replaced by a subsequent one reached two times, causing the lower Area of the boom profile advantageously right is insensitive to manufacturing deficiencies, especially with regard to dimensional deviations at the bottom Bending radius. If dimensional deviations have occurred, leave it this by appropriate choice of the angle between the sideways beveled bevel and the subsequent rounded Balance the section in a simple way. So is the desired width of the lower flange can be exactly maintained and adjustable to the width of the top chord.

In the preferred embodiments of the invention Cantilever profile, in which each other in the lower profile area opposite, flat bends in the side sections and also one that intersects the vertical axis of gravity Horizontal web are provided, are the advantages of Rectangular profile and the advantages of the round profile in particular happily combined.

Figuren 1 bis 8

bis in Form von schematisierten Querschnitten durch Teleskopausleger, acht verschiedene Ausführungsformen von erfindungsgemäßen Auslegerprofilen.

The invention is described below using exemplary embodiments and with reference to the drawing. In this show:

Figures 1 to 8

up to in the form of schematic cross sections through telescopic booms, eight different embodiments of boom profiles according to the invention.

In all the embodiments described in detail below is the top chord, i.e. the upper part of the Boom profile, essentially the same shape. The top chord is formed from an upper, horizontal, flat surface Web section, which is angled downwards by 90 °, rounded corners thigh-like and on both sides of the upper web section into two vertical, flat web sections is transferred. The different embodiments differ in the lateral length of the Top chord vertical webs and in the training of the lower ends of the vertical webs adjoining lower rounded ones Sections of the overall profile.

The stretches across the entire profile in all figures dash-dotted, vertical and horizontal lines correspond to the vertical axis of gravity Iy and horizontal axis of gravity Ix by area inertia calculations are determined. In addition, all embodiments are designed such that the vertical axis of gravity Iy also serves as a mirror axis. That is, the left and right boom profile pages are mirror images in relation formed on the vertical axis Iy. All embodiments is still one that is included internally to the overall profile Angle a between the top flange vertical web and one adjacent sideways sloping bend in the area from 135 to 180 ° is common. Mirror symmetrical to is predominantly described left-hand profile half a right-hand profile half is formed.

According to a first exemplary embodiment shown in FIG. 1, the lateral vertical web belonging to the upper chord is continued with a laterally oblique, flat bevel 15 of length x ₁ , which is inclined downward to the vertical axis of gravity Iy. The fold is preferably arranged at a height of the vertical web in such a way that the fold overlaps with the horizontal axis of gravity Ix. At the lower end of the bend is a circular arc section 16 with the radius R ₁ and the center K1. Finally, a lower horizontal web section 17 with the length M _{1 is} arranged at the lower horizontal outlet of the circular arc 16. This lower horizontal web section 17 connects the lower ends of the left-hand circular arc section 16 and a right-hand, mirror-symmetrical circular arc section 16 ', the center point of which is designated K11.

The two ends of the lower horizontal section 17 go tangentially into the adjacent circular arc sections 16 and 16 'over. The center points K1 and K11 of the two circular arc sections 16 and 16 'are both of the same kind Major axes Iy and Ix spaced apart, the two centers on both sides of the vertical axis of gravity Iy and provided below the horizontal axis of gravity Ix are. The center point K1 lies vertically above the left-hand side End of the horizontal web 17 and the center K11 lies vertically above the right-hand end of the Horizontal web 17. Consequently, the length M1 is equal to that Distance between the center points K1 and K11. The same applies to the position of the radius centers as well as for their distance from each other and the length of the lower one Horizontal webs in the embodiments according to figures 2, 3 and 9.

A particular advantage of this cantilever profile according to FIG. 1 can be seen in the fact that many mass points of the lower profile section are at a large distance from the axis of gravity Iy and thus a large moment of resistance against bending about the bending axis Ix is ensured. Furthermore, there is an advantageous introduction of force into the lower profile section, since the membrane effect can come into play at the rounded force introduction points. Finally, a further optimization of the sensitivity of the lateral vertical web assigned to the upper chord against bulging, which is appropriate to the user wishes, is possible by varying the length of the arc sections 16 and 16 'and the length x _{1 of} the oblique fold 15.

A second embodiment of the boom profile is shown in Fig. 2. At the lower end of the vertical web assigned to the upper chord, a laterally inclined, flat bevel 25 with the length x ₂ does not directly adjoin (see FIG. 1). Rather, the vertical web and the bevel 25 are connected to one another via a rounding 28 in such a way that there is no bend edge. A circular arc section 26 with the radius R _{2 is then} arranged at the lower end of the lateral, oblique fold 25. The center points K ₂ (left-hand side) and K ₂₂ (right-hand side) of the circular arc sections 26 (left-hand side) and 26 '(right-hand side) are arranged in relation to the major axes Iy, Ix in such a way that their distances from both major axes are the same. The two circular arc sections 26 and 26 'are connected to one another with the aid of a flat horizontal web 27. The length of the horizontal web 27 is designated M ₂ . The length M ₂ corresponds to the distance between the center points K2 and K22 from one another.

Advantageously, in the embodiment according to FIG. 2, there are large possible variations in the lengths x ₂ and M _{2 of} the flat sections 25 and 27 by changing the parameters M ₂ , R ₂ , x ₂ and the radius of the arc 28. Furthermore, in FIG 2, the jib profile shown does not have any kinked edges, since rounded sections with tangential transitions always follow straight (flat) sections.

This means that there are practically no moments from circumferential stresses. The generation of membrane stresses, especially in the rounded sections 26 and 26 ', ensures an advantageous introduction of the transverse forces into these rounded sections. Furthermore, there is an increased stiffness of the profile to the axis of gravity Iy due to the length M _{2 of} the lower horizontal web 27, since the mass points of this length M _{2 are} weighted very heavily (third power) in the stiffness calculation.

A third embodiment of the cantilever profile (according to FIG. 3) is derived from the second embodiment. A first difference is that the rounded region 28 crosses the horizontal axis of gravity Ix in the second embodiment, while a similar rounded section 38 of the third embodiment is only set below the horizontal axis of gravity Ix. Furthermore, although the center points K ₃ and K _{33 of} the left and right sides of the circular arc sections 36 and 36 'on the left and right sides are arranged similarly to FIG. 2 below the horizontal axis of gravity Ix, however, these center points K ₃ , K _{33 are} so positions that their distances from the horizontal axis of gravity Ix are shorter than from the vertical axis of gravity Iy. Otherwise, the laterally oblique bend 35 adjoining the upper chord vertical section downwards has the length x ₃ , the arc section 36 (or 36 ') has the radius R ₃ and the horizontal, flat web section 37 has the length M ₃ . The flat section 37 connects the left and right-hand rounded sections 36 and 36 'to one another. The length M ₃ corresponds to the distance between the center points K3 and K33 from one another.

A particular advantage of the third embodiment (FIG. 3) is a large section modulus against the (bending) axis Ix, since large parts of the mass points of the lower section are located relatively far from the axis of gravity Iy. Furthermore, there is an advantageous introduction of force into the arc sections 36 and 36 'due to their membrane action. Furthermore, no moments are to be expected at the transition point between the section 38 and the vertical web section of the upper chord 34 which adjoins upwards. Since no buckling edge is formed between these two sections, circumferential stresses generated by the radial introduction of forces can essentially not result in corresponding moments. Thus there is a slight tendency of the lower horizontal web portion 37 to bulge. The buckling behavior in the area of the lateral vertical web can be influenced by the length x _{3 of} the flat, obliquely bent edge 35. The third embodiment essentially combines the advantages of the two previous embodiments.

A fourth embodiment of the cantilever profile shown in FIG. 4 initially provides, similarly to the first exemplary embodiment, a laterally oblique, flat fold 45 with the length x ₄ , which intersects the horizontal axis of gravity Ix, following the upper chord vertical section. Similar to the previous three embodiments, the fold is identical to the tangent which is formed at the upper end of the arc section 46 adjoining at the bottom, ie there is no fold edge below the fold 45, as in the previous three embodiments as well. The arc section 46 with the radius R ₄ now connects the left fold 45 with the right fold 45 'of the cantilever profile. The center point K ₄ of the arc section 46 is provided above the horizontal axis of gravity Ix, but on the vertical axis of gravity Iy. If necessary, the arc radius of the arc section 46 immediately adjacent to the folds 45, 45 'may be smaller than R ₄ , so that the entire arc 46 is composed of three individual arcs.

The tangential transitions between the oblique fold 45 and the arc section 46 advantageously prevent the formation of moments due to circumferential stresses. This embodiment allows the height of the vertical web belonging to the upper chord and thus its buckling behavior by varying the radius of the arc 46 which is present at the bend 45, as well as the arc length caused by this radius and by varying the length x _{4 of} the bend 45 according to the to determine the respective static requirements. Forming the curved section 46 with two different radii results in a particularly favorable buckling behavior in the lower profile section 43.

A fifth embodiment of the cantilever profile is shown in FIG. 5. In this case, the laterally inclined, flat bevel 55 which adjoins the vertical web belonging to the upper web and is arranged below the horizontal axis of gravity Ix. The bevel has the length x ₅ . The lower end of this left-sided bevel 55 is connected by an arc section 56 to the lower end of a mirror-symmetrical, right-hand, flat bevel 55 '. The arc section 56 has a radius R ₅ , and the associated circular arc center K ₅ is similar to the fourth exemplary embodiment above the horizontal axis of gravity Ix and the vertical axis Iy intersecting.

A relatively large radius R _{5 of} the arc section 56 ensures a large moment of resistance of the boom against bending against the horizontal axis Ix. The fact that the underside of the cantilever profile is largely rounded in this fifth embodiment, there is a particularly low tendency to bulge. The angular position and the length x ₅ in the force application area of the folds 55 can be determined flexibly according to the user requirements with regard to the lateral and lateral lower sensitivity to bulging.

The sixth embodiment of the cantilever profile according to FIG. 6 represents a variation of the fifth embodiment. The main difference is that a larger radius R ₆ (cf. radius R _{5 of} the circular arc section 56 in the fifth embodiment) was selected for a circular arc section 66 , Accordingly, the associated circular arc center K _{6 is arranged} significantly higher above the axis of gravity Ix on the vertical axis Iy, the vertical web 64 belonging to the upper flange, in particular below the axis of gravity Ix, is longer and the lateral fold 65 between the vertical web 64 and the arc section 66 is stronger inclined to the vertical axis of gravity Iy.

Differentiate the advantages of this sixth embodiment different from those already for the fifth embodiment were specified, only in intensity.

A seventh embodiment of the cantilever profile is shown in FIG. Instead, the vertical web belonging to the upper chord is transferred directly into the curved section 76. The transition from vertical web to arch section is preferably arranged essentially at the level of the horizontal axis of gravity Ix. The left-hand arc section 76 has a radius R ₇ with a circular arc center K7 at the intersection of the two major axes. The radius R ₇ preferably corresponds essentially to the distance between the vertical center of gravity Ix and the vertical web 74 belonging to the upper chord. The two arc sections 76 and 76 'are connected to one another via a lower horizontal, flat web section 77. The web section 77 has the length M ₄ . In a preferred embodiment, the transition between circular arc section 76 and web section 77 is designed in such a way that no kink edge is formed by means of a transition arc with a small radius.

The seventh embodiment advantageously adjusts large moment of resistance against bending against the axis Ix ready because a large part of the mass points of the lower profile section a large distance from the vertical axis of gravity Iy has. The rounded sections ensure as a result the membrane effect a particularly favorable force transmission in the overall profile. Furthermore, essentially none occur Moments in the transition area to the lateral vertical bars because the circumferential stresses of the arc section 76 or 76'directed directly or tangentially into the vertical webs become.

An eighth embodiment is shown in FIG. This embodiment largely corresponds to the first embodiment shown in FIG. 1, but has no laterally inclined bends. At the lower ends of the vertical webs assigned to the upper chord, an arc section 86 with the radius R _{8 is connected} on the left side and an arc section 86 ′ with the radius R ₈ on the right side. Between the two circular arc sections 86 and 86 'there is a lower horizontal section 87 with a comparable length M ₅ . As in the first, second and third embodiment, the center points K ₈ and K _{88 are} each equally spaced to the side of the vertical axis of gravity Iy and equally spaced below the horizontal axis of gravity Ix. The length M _{5 of} the horizontal section 87 corresponds to the distance between the center points K ₈ and K ₈₈ from one another. As in the first, second and third embodiment of the invention, the membrane tension state is also ensured in the eighth embodiment by the tangential transitions of the circular arc section 86, 86 ′ into the horizontal web section 87.

The eighth embodiment advantageously adjusts large moment of resistance against bending against the Ix axis ready because a large part of the mass points of the lower profile section a large distance from the vertical axis of gravity Iy has. The rounded sections ensure as a result the membrane effect a particularly favorable force transmission, both in the two vertical webs and in the horizontal web 87. There are also no moments in the transition areas to the horizontal bar and to the two vertical ones Web sections because the circumferential stresses of the Arc section 86 and 86 'introduced tangentially into all webs become.

For all embodiments with lower horizontal web sections, i.e. for the embodiments according to FIG. 1, 2, 3, 7 and 8 applies that their length M at least 5%, maximum 28% of the total profile width (X direction). at multi-section booms show the profiles of the base part nearby parts preferably length dimensions M from 5 to 17% of the respective total profile width while the profiles the inner, i.e., the more distant parts of the tele part preferably length dimensions M from 12 to 28% have their respective overall profile width.

The length dimensions X of the bevels on the side is preferred in all embodiments of the invention 5 to 28%, based on the total profile height (Y-direction).

Further embodiments can be formed in that previously provided crease edges between the individual Profile sections through rounded sections with a small radius be replaced.

In all of the above-described boom profiles at least the lower rounded or round sections made with the help of edging. Doing this will be consecutive more or less narrow strips of material folded. Through a corresponding number of successive folding steps round profile parts or profile sections can be reached that are practically non-existent in practice ideally distinguish round designs. Such a practice is known as POLYGONZUG.

1. ergibt sich aus den Kantungen eine gesteigerte Profilsteifigkeit im Vergleich zu ebenen ungekanteten Wandungsabschnitten und

2. wird durch die Kantungsvorgänge jeweils eine Kaltverfestigung des verwendeten Stahlwerkstoffes herbeigeführt, die zu einer nicht unbeträchtlichen Erhöhung der Streckgrenze beiträgt.

By using the edge to shape the cantilever profile sections and in particular to form the lower round or rounded profile section, two particular advantages are achieved with regard to the strength of the cantilever profile produced:

1. the edging results in an increased profile rigidity compared to flat, non-edged wall sections and

2. the edging processes bring about a strain hardening of the steel material used, which contributes to a not inconsiderable increase in the yield strength.

As a result, smaller dimensions can be made for the cantilever profile Sheet thicknesses and constructions are used without there is a loss of strength.

Claims (8)

1. A jib profile, more particularly for telescopic jibs of cranes and crane vehicles, with a substantially half-box-shaped top portion with side walls extending parallel to the vertical axis (ly) through the centre of gravity of the jib profile and with a bottom profile portion which has at least one arcuate portion and which is connected to the ends of the parallel side walls of the top portion,
   characterised in that the regions of the bottom profile portion which are connected to the ends of the parallel side walls of the top profile portion are arranged opposite one another in the form of flat symmetrical bends (15, 25, 35, 45, 55, 65) directed obliquely inwards and including in each case an angle "alpha" with the parallel side walls of the top profile portion, and in that an arcuate portion (16, 16', 26, 26', 36, 36', 46, 56, 76, 76', 86, 86') adjoins the bottom ends of said inwardly directed flat bends.
2. A jib profile according to claim 1,
   characterised in that a horizontal web (17, 27, 37, 77, 87) divided centrally from the vertical axis (ly) through the centre of gravity of the jib profile is provided and extends parallel to the horizontal axis (lx) through the centre of gravity, an arcuate portion (16, 16', 26, 26', 36, 36', 76, 76', 86, 86') of the bottom profile portion being connected to both ends of said horizontal web.
3. A jib profile, more particularly for telescopic jibs of cranes and crane vehicles, with a substantially half-box-shaped top portion with side walls extending parallel to the vertical axis (ly) through the centre of gravity, a bottom profile portion which comprises two arcuate portions and which is connected to the ends of the parallel side walls of the top portion, and with a horizontal web (77, 78) divided centrally from the vertical axis (ly) through the centre of gravity of the jib profile and extending parallel to the horizontal axis (lx) through the centre of gravity of the jib profile, one of the arcuate portions (76, 76', 86, 86') being connected to each of the two ends of the horizontal web, characterised in that the radii (R₇, R₈) of the two arcuate portions (76, 76', 86, 86') are distinctly greater than the rounding radii in the region of the top profile portion and in that both the top profile portion and the bottom profile portion are each made in one piece.
4. A jib profile according to claim 3,
   characterised in that the radii (R₇) of the two arcuate portions (76, 76') intersect at the point of intersection of the vertical axis (ly) through the centre of gravity and the horizontal axis (lx) through the centre of gravity.
5. A jib profile according to claim 3,
   characterised in that the centres (K_8, K₈₈) of the two arcuate portions (86, 86') are equally spaced from the vertical axis (ly) through the centre of gravity and are respectively equally spaced beneath the horizontal axis (lx) through the centre of gravity, the length of the horizontal portion (87) being equal to the distance between the centres of the arcs (K₈, K₈₈).
6. A jib profile according to claim 1 or 3,
   characterised in that the radii of the arcuate portions (16, 16', 26, 26', 36, 36', 86, 86') have the circle centres (K₁, K₁₁, K₂, K₂₂, K₃, K₃₃, R₄, R₅, R₆, R₈) beneath the horizontal axis (lx) through the centre of gravity of the jib profile.
7. A jib profile according to claim 1 or 3,
   characterised in that the arcuate wall portions (16, 16', 26, 26', 36, 36', R₈) have their circle centres at equal distances from the vertical axis (ly) through the centre of gravity and the horizontal axis (lx) through the centre of gravity, but beneath the latter horizontal axis.
8. A jib profile according to claim 1,
   characterised in that the arcuate portion (46, 56, 66) has its circle centre (K₄, K₅, K₆) above the horizontal axis (lx) through the centre of gravity on the vertical axis (ly) through the centre of gravity.

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