EP4263978A1 - Frame for carrying a concrete-distribution boom - Google Patents

Abstract

The present invention relates to a frame for carrying a concrete-distribution boom, the frame comprising a carrier profile (13) which has: at least one force-absorption region (16, 17), for absorbing a flow of force exerted by the concrete-distribution boom; and a force-dissipation region (18), which is spaced apart in the longitudinal direction of the carrier profile (13), for dissipating the flow of force into the ground. The carrier profile (13) comprises at least two profiled sheets (20, 21), which are each bent along at least one bending axis (26, 27, 31) and are assembled along at least two connection lines (22, 23) to form a hollow profile. The carrier profile formed by bent profiled sheets is simple to produce and flexible to use.

Description

Frame for carrying a concrete placing boom

The subject matter of the present invention is a framework for carrying a concrete placing boom.

A concrete placing boom, which is carried by a frame, is regularly used to spread concrete using mobile or stationary concrete pumps. For this purpose, a so-called mast bracket is usually fixed to the frame, on which the concrete spreader is mounted so that it can rotate about a vertical axis. The concrete placing boom can also be constructed from a number of boom segments which are designed to be pivotable relative to one another in order to achieve a desired application location. The concrete, which is pressurized by a pumping device, can be discharged at a desired location via a concrete delivery line routed along the concrete placing boom.

In particular, when the mast segments are in an extended state, large load moments occur which must be introduced into the framework and then dissipated into the subsoil. For this purpose, the framework usually has two support profiles which are aligned in the longitudinal direction of the framework and serve to transmit the flow of force.

In principle, it is known in the state of the art to use a framework with carrier profiles which consist of a closed square tube frame produced by extrusion. Square tube frames of this type have a high level of stiffness and stability. The disadvantage of the closed square tube frames, however, is that they are expensive and inflexible to manufacture. Against this background, it is the object of the present invention to provide a frame for supporting a concrete placing boom and a concrete pump with such a frame that at least partially avoids the above disadvantages. This problem is solved with the features of the independent claims. Advantageous embodiments are specified in the dependent claims.

The framework according to the invention for supporting a concrete placing boom comprises a carrier profile which has at least one force absorption area for absorbing a force flow exerted by the concrete placing boom and a force dissipation area spaced apart in the longitudinal direction of the carrier profile for dissipating the force flow into a subsoil. The carrier profile comprises at least two profile sheets, each of which is bent along at least one bending axis and assembled along at least two connecting lines to form a hollow profile.

First, some of the terms used in the present description are explained. The framework according to the invention has at least one and preferably two carrier profiles which can be aligned parallel to one another, for example. For the sake of simplicity, only the configuration of a single carrier profile is explained at many points within the scope of the present description. It goes without saying that the framework according to the invention can also have two or more carrier profiles, which can also have the features explained in the context of the present description. The carrier profile usually has a longitudinal direction along which the flow of forces is directed from the force absorption area to the force dissipation area. This longitudinal direction can correspond to the longitudinal direction of the framework. The framework can in particular have a mast bracket, which is used to connect the concrete placing boom. The mast bracket is usually firmly connected to the carrier profile in the force absorption area of the carrier profile and is preferably set up for the rotatable mounting of the concrete placing boom about a vertical axis. The framework can also have a support system connected to the carrier profile in the force dissipation area, which is designed to introduce the force flow transmitted by the carrier profile into the subsoil.

Provision can be made for a substantial part (for example more than 10%, more than 20% or more than 30%) of the force flow to be passed on from the force absorption area along the carrier profile (or possibly along the carrier profile) to the force dissipation area. The framework differs from support structures in which the flow of forces from the mast head is introduced directly into a support structure formed from support leg boxes and into associated support legs that can be moved or swiveled out (see, for example, EP 3 369 876 A1). In the case of the present frame, rear support legs are not absolutely necessary, since the carrier profile, together with a support system attached to it, already assumes a corresponding rear support function. Since rear support legs drive or Swiveling out take up a lot of space during use, the space requirement of the present frame structure is correspondingly reduced. In addition, there is more loading space available on the frame due to the lack of rear support legs.

Within the scope of the invention, it was recognized that the canted profiled sheets make it possible to produce a carrier profile that is economical and reliable and flexible in use. In particular, it has been shown that assembling along two connecting lines, on which the profile sheets can be screwed or welded together, for example, leads to a stable and low-distortion carrier profile. In addition, the cross-sectional shape of the support profiles can be adjusted much more easily by suitably selecting the bending axes and bending angles compared to previously known square tube frames, the shape of which is predetermined by the extrusion process.

Support profiles of a framework are also regularly used to attach add-on parts to it. The add-on parts can be, for example, platform holders, parts of the support system, holding devices for the pumping device, for lines or for a water tank, a connecting strut for connecting the mast bracket to the carrier profile and/or parts of the mast support bracket. In a preferred embodiment, at least one of the profiled metal sheets therefore has a fastening opening for fixing an add-on part to the carrier profile. The fastening opening can form a passage to an interior area of the hollow profile. In contrast, in the case of square tube frames produced by extrusion, which are known from the prior art, the subsequent production of fastening openings is extremely complex, so that add-on parts are usually fastened by means of welded connections. This causes high costs and leads to low flexibility. On the other hand, the fastening openings prefabricated at the desired positions on the carrier profile of the framework described here enable a flexible and detachable assembly of add-on parts. In addition, it is easily possible to provide the profiled sheets with a desired number of fastening openings before assembling them into the hollow profile and preferably also before edging the profiled sheets and only assembling the profiled sheets into edging and the hollow profile in a subsequent step. In addition, the detachability of the attachments free spaces can be created fen, the repair and maintenance of otherwise allow components blocked by the dismantling parts.

Finally, it has been shown that a weakening of the stability of the carrier profile caused by the fastening openings can easily be compensated for by a corresponding (larger) dimensioning of the hollow profile or the profile sheets. In particular with a suitable selection of the bending axes and bending angles, within the scope of the invention, an existing installation space can be better utilized in a simple manner and the stability of the carrier profile can be increased in this way.

An access opening may be provided adjacent a mounting opening. In this way, easy access to a fastener is possible, which can be used to fix an attachment in the mounting hole. This applies in particular when the fastening opening forms a passage to an interior area of the hollow profile. The attachment openings can have an area of more than 0.3 cm ² . The area of the attachment openings can be, for example, in a range between 0.3 cm ² and 20 cm ² , preferably between 0.5 cm ² and 10 cm ² and more preferably between 0.8 cm ² and 2 cm ² . Access openings can have an area greater than 100 cm ² . For example, the area of the access openings can be between 100 cm ² and 500 cm ² , preferably between 120 cm ² and 400 cm ² , more preferably between 140 cm ² and 300 cm ² .

In one embodiment, the connecting lines can be aligned parallel to the longitudinal direction of the carrier profile. In this case, the flow of forces is directed along the connection lines, which reduces the load on the connection and increases the rigidity of the hollow profiles. In one embodiment, the bending axes are aligned parallel to the longitudinal direction of the carrier profile. The stiffness of the hollow profiles can also be improved by this measure, since the flow of forces runs along the bending axes.

The profile sheets can be joined together along the connecting lines to form the hollow profile. The joint connection can be a welded connection, for example. Alternatively, other joining connections, e.g. B. an adhesive connection in question. The use of a welded connection leads to very stable and torsion-resistant hollow sections. It has also been shown that the welding distortion caused by the heat effect during welding is extremely small, since each profiled sheet, viewed in cross-section, is welded at two opposite ends to the respective adjacent profiled sheet. A material distortion caused by the welding is thereby almost eliminated.

In particular, the hollow profile can be composed of two profile sheets. In this case, viewed in cross section, the profile sheets can be subdivided into sections by the bending axes. Outer sections of a profiled sheet metal can be at an angle of between 75° and 105°, preferably between 85° and 95° and more preferably at an angle of essentially 90° to one another. In addition, an external profiled sheet section of one of the profiled sheets in the area of the connecting line can assume an angle of between 75° and 105°, preferably between 85° and 95° and more preferably an angle of essentially 90° to an adjacent external profiled sheet section of the other of the profiled sheets . In one embodiment, the hollow profile also has a maximum cross-sectional width and a maximum cross-sectional height, with the connecting lines in one of the maximum cross-sectional width and the maximum cross-sectional height formed notional rectangle diagonally opposite. In this case, the profile sheets can in particular be L-shaped. It has been shown that the features described above also contribute to the fact that a welding distortion present in the area of the connecting lines is eliminated as completely as possible, so that the finished hollow profile is as distortion-free as possible.

In one embodiment, one of the profile sheets can have a partial section defined by a bending axis, which forms an underside of the carrier profile and whose width is smaller than a maximum cross-sectional width of the hollow profile. This can be achieved in particular by a suitable selection of the bending axes and bending angles, so that the cross section of the hollow profile increases starting from the underside towards the top. Since the installation space is often tight, particularly in the lower region of the carrier profile, the installation space available further up can be better utilized and the stability of the carrier profile can be increased by means of the cross-section expansion mentioned.

The hollow profile can have a cross-sectional width that is between 10 cm and 45 cm and preferably between 10 cm and 16 cm. A cross-sectional height of the hollow profile can be in the range between 20 and 90 cm, preferably between 20 cm and 32 cm.

Furthermore, it can be provided that the profiled sheet, viewed in cross-section, comprises an overhang projecting beyond the connecting line, the extension of which is preferably between 0.5 cm and 5 cm, more preferably between 1 cm and 3 cm. The overhang simplifies the production of the hollow profile, in particular when using a welded connection, and one that is continuous over the longitudinal extent secure connection guaranteed. In particular, the guidance of the welding torch is made easier and the weld seam can easily be implemented as a fillet or HY seam, for example. In addition, force application points (e.g. through the articulation of struts) can be implemented more easily in the area of the overhang.

The subject matter of the invention is also a framework for supporting a concrete placing boom, with a carrier profile which has at least one force absorption area for absorbing a force flow exerted by the concrete placing boom and a force dissipation area, spaced apart from the force absorption area in the longitudinal direction, for dissipating the force flow into a subsoil. In addition, in the force absorption area, the carrier profile comprises a tab that protrudes upwards for the absorption and transmission of at least part of the force flow. In particular, two spaced apart force absorbing areas in the longitudinal direction of the support profile can be provided for absorbing a force flow exerted by the concrete placing boom, wherein the tab can be arranged in one of the force absorbing areas that is at the rear with respect to the longitudinal direction. In the front of the force absorption areas, which can be arranged in particular at the front longitudinal end of a carrier profile, a mast bracket for mounting the concrete placing boom can usually be placed on the carrier profile.

The second force receiving area is longitudinally spaced from the first force receiving area. The distance can, for example, correspond to a length that is between 10% and 90%, preferably between 25% and 75% of the longitudinal extension of the carrier profile. The tab may extend longitudinally over a length ranging between 3% and 50%, preferably between 5% and 30% of the longitudinal extent of the carrier profile. The framework described above can be further developed by further features explained in the context of the present description.

The framework can in particular have a mast block which is connected to the bracket by means of a connecting strut, the connection preferably being made by means of a bolt connection.

The tab can also have an upper edge whose orientation corresponds to an orientation of the connecting strut with an angular deviation of less than 15°, preferably less than 10°, more preferably less than 5°. A maximum extent of the tab along a vertical axis can be in a range between 3 cm and 50 cm, preferably in a range between 5 cm and 45 cm and more preferably in a range between 10 cm and 35 cm. In addition, the extent along the vertical axis can decrease in the direction of the rear end of the carrier profile. The tab can be formed by a sheet metal part, which is preferably aligned parallel or essentially parallel to the longitudinal direction of the carrier profile. The tab can also be designed as an integral part of the carrier profile.

In one embodiment, the carrier profile comprises at least two profiled sheets, each of which is bent along at least one bending axis and assembled along at least two connecting lines to form a hollow profile, with the tab being designed as an integral part of one of the profiled sheets.

The present invention is also a concrete pump, comprising a frame according to the invention, a associated concrete placing boom as well as a pumping device designed for spreading concrete. The arrangement can be further developed by further features described above in connection with the frame structure according to the invention.

The pumping device is preferably mounted on the frame according to the invention. The concrete pump can be a stationary or a mobile concrete pump. In the case of a mobile concrete pump, the frame can be designed to be connected to the chassis of a truck.

The subject matter of the present invention is also a method for producing a carrier profile with the following steps:

providing at least two profile sheets;

Production of at least one fastening hole in at least one of the profile sheets;

Bending the profiled sheets along a bending axis of the respective profiled sheet;

Assembling the profile sheets into a hollow profile;

Connecting the profile sheets along two connecting lines.

The method can be enhanced by further features described above in connection with the frame structure according to the invention be trained. In particular, the profile sheets can be connected by means of a joining method, in particular by welding.

Further advantages and refinements of the invention result from the dependent claims, the description and the accompanying drawings.

It goes without saying that the features mentioned above and those still to be explained below can be used not only in the combination specified in each case, but also in other combinations or on their own, without departing from the scope of the present invention.

The invention is illustrated by way of example in the drawings and described in detail below with reference to the drawings.

Figure 1 shows a three-dimensional side view of a frame according to the invention,

FIG. 2 shows a three-dimensional side view of a carrier profile used in the embodiment in FIG.

Figure 3 shows a cross-sectional view of the carrier profile of Figure 2,

FIG. 4 shows a three-dimensional side view of a further embodiment of a framework according to the invention and

FIG. 5 shows a three-dimensional side view of a carrier profile used in the embodiment of FIG. FIG. 1 shows a three-dimensional side view of a frame 100 according to the invention. The framework 100 comprises two support profiles 13 running along its longitudinal direction and aligned parallel to one another, as well as a mast bracket 14 connected to the support profiles 13 . A concrete placing boom, not shown in the figure, can be connected to the boom block 14 in a manner known in principle, with the aid of a rotatable bearing. Also connected to the mast trestle 14 are support leg boxes 11 in which extendable and retractable support legs 12 are mounted. In the present case, the support leg boxes 11 also rest on the carrier profiles 13 .

The mast bracket 14 is connected on the one hand to the first connection areas 16 positioned at the front ends of the carrier profiles 13 . On the other hand, the mast bracket 14 is connected via connecting struts 15 designed as corner profiles to second connecting regions 17 spaced apart in the longitudinal direction of the carrier profiles 13 . The two connecting areas 16 , 17 represent force absorbing areas within the meaning of the present invention.

A force dissipation area 18 is located at the rear end of the carrier profiles 13 (on the right in FIG. 1). In this force dissipation area, the support profiles 13 are connected to a support system that includes a cross member 19b and two legs 19a. The two force absorbing areas 16 , 17 are spaced from the force dissipation area 18 in the longitudinal direction of the profiled beam 13 , so that a force flow introduced via the force absorbing areas 16 , 17 is conducted in the longitudinal direction of the profiled beam 13 to the force dissipating area 18 arranged at the rear end. The flow of forces is illustrated by the arrows 10 . Crossbars 9 are also connected to the carrier profiles 13 . The connection between the crossbars 9 and the carrier profiles 13 is made by means of in Figure 1 not recognizable fnungen present in the carrier profiles 13 Befestigungsöf.

FIG. 2 shows a three-dimensional side view of a section of a carrier profile 13 used in the embodiment of FIG. FIG. 3 shows a cross-sectional view of this carrier profile 13 . In the views of Figures 2 and 3 it can be seen that the carrier profile 13 comprises two profiled sheets 20, 21 which are combined to form a hollow profile by being welded to one another along two connecting lines 22, 23. This creates a hollow profile with a cross-sectional width 24 of about 14 cm and a cross-sectional height 25 of about 28 cm. The profile sheet 21 has overhangs of about 2 cm that protrude beyond the connecting lines 22 , 23 , which do not correspond to the cross-sectional width 24 or Section height 25 are added.

The profile sheet 20 is bent about a bending axis 27 by about 90°, so that the profile sheet 20 has two partial sections 20a, 20b separated from one another by the bending axis 27 and standing at a 90° angle to one another. The profile sheet 21 is bent about two bending axes 26 , 31 by approximately 45° each, so that it has three partial sections 21 a , 21 b and 21 c separated from one another by the bending axes 26 , 31 . Sections 21a and 21c of profile sheet 21 located at the edge and sections 20a and 20b of profile sheet 20 are at an angle of approximately 90° to one another. In addition, the connecting lines 22 , 23 lie diagonally opposite one another in an imaginary rectangle formed by the cross-sectional width 24 and the cross-sectional height 25 .

It has been shown that a reliable and stable welded connection is produced in the case of profile sheets standing perpendicular to one another and when using the projection mentioned can be . In addition, component distortion caused by heat during welding can be almost completely avoided due to the symmetrical arrangement of the connecting lines, so that no subsequent straightening of the carrier profile 13 is necessary.

The partial section 21c of the profile sheet 21 , which forms an underside of the carrier profile 13 , has a width that is less than the maximum cross-sectional width 24 of the carrier profile 13 . This means that the carrier profile 13 takes up less space in the lower area. The selection of the bending axes 26 , 31 increases the cross section of the carrier profile from the underside in the direction of the upper side until it reaches the entire maximum cross-sectional width 24 at the level of the bending axis 26 . This enlargement of the cross section means that the available space in the upper area of the carrier profile, which is often less tightly dimensioned, can be better utilized and the stability of the carrier profile 13 can thus be increased.

Due to the above-described design of the profile sheet 21 with three sections 21a, 21b, 21c standing at an angle to one another, free space can be made possible in the lower area, for example for chassis parts (such as protruding spring brackets) or fender mounts, despite the large cross section in the upper area of the carrier profile good accessibility is also guaranteed in the event of service. The inclined section 21b, which is angled at about 45° to the sections 21a and 21c, also creates a harmonious flow of forces with regard to the cross-sectional values ( moment of inertia , bending, torsion and shear flow ) compared to other types of recesses (such as a recess angled at 90°). allows the greatest possible utilization of the installation space. FIG. 2 also shows fastening openings 29 arranged in the profile sheet 21 and access openings 28 arranged adjacent to the fastening openings 29 . Add-on parts, such as the crossbars 9 shown in FIG. 1, can be used in the fastening openings, which are missing in FIG. 2 for the sake of clarity. Because of the fastening openings 29, no effort is required to produce a welded connection between an add-on part and the carrier profile. With the fastening openings, add-on parts can be easily screwed to the carrier profile 13 and, if necessary, removed again or moved.

FIG. 4 shows a three-dimensional side view of a further embodiment of a frame 100 according to the invention. FIG. 5 shows a three-dimensional side view of the carrier profiles 13 used in the embodiment in FIG. Such elements, which are identical or similar in the embodiment of FIGS. 1 to 3, are provided with the same reference symbols in FIGS. Compared to FIG. 1, FIG. 4 also shows a concrete feed container 36 , a concrete line 35 connected thereto and mast support blocks 37 , 38 arranged on the frame 100 .

In addition, the embodiment of FIGS. 4 and 5 differs in particular with regard to the connecting struts 15 and their connection to the carrier profiles 13 in the force introduction area 17 . In the embodiment of FIG. 4, the connecting struts 15 are designed as round struts, which are connected to the carrier profile 13 via a bolt connection.

For this purpose, the profiled sheet metal 21 has a projection of about 20 cm above the cross-sectional height of the carrier profile 13 Tab 40 which is provided with a through hole 41 for producing the bolt connection. The bracket 40 is an integral part of the profile sheet 21 , so that a force flow introduced via the connecting struts 15 is introduced directly into the profile sheet 21 and thus into the carrier profile 13 . In order to enable a particularly good flow of forces, the lug 40 has an upper edge 42 whose orientation corresponds approximately to an orientation of the connecting struts 15, with an angular deviation of the orientations preferably being less than 5°. The extent of the tab 40 along a vertical axis is correspondingly greatest in the area of the bolt connection and decreases in the direction of the rear end of the profiled carrier 13 .

Claims

Framework (100) for supporting a concrete placing boom, with a carrier profile (13), which has at least one force absorbing area (16, 17) for absorbing a force flow exerted by the concrete placing boom and a force dissipation area (18) spaced apart in the longitudinal direction of the carrier profile (13) for dissipation of the flow of forces into a substrate, with the carrier profile (13) comprising at least two profiled sheets (20, 21), each folded along at least one bending axis (26, 27, 31) and along at least two connecting lines (22, 23) to form a Hollow profile are assembled. Frame according to claim 1, wherein the profile sheet (20, 21) has a fastening opening (29) for fixing a

Attachment on the carrier profile (13). Framework according to Claim 2, in which the fastening opening (29) forms a passage to an interior region of the hollow profile. Framework according to claim 2 or 3, in which the profiled sheet (20, 21) has an adjacent to the fastening opening

(29) arranged access opening (28), wherein preferably the attachment opening has an area of more than 0.3 cm ² and / or the access opening has an area of more than 100 cm ² . Framework according to one of Claims 1 to 4, in which the connecting lines (22, 23) and/or the bending axes (26, 27, 31) are aligned parallel to the longitudinal direction of the carrier profile (13). Framework according to one of Claims 1 to 5, in which the profile sheets (20, 21) are joined to one another and preferably welded to one another along the connecting lines (22, 23) to form the hollow profile. Framework according to one of Claims 1 to 6, in which the hollow profile is composed of two profile sheets (20, 21). Framework according to Claim 7, in which the profile sheets (20, 21), viewed in cross section through the bending axes (26, 27, 31), are subdivided into partial sections (20a, 20b, 21a, 21b, 21c), with external partial sections (20a, 20b, 21a, 21c) of a profile sheet (20, 21) form an angle of between 45° and 135°, preferably between 75° and 105°, more preferably between 85° and 95° and particularly preferably an angle of essentially 90° to one another . Framework according to Claim 7 or 8, in which the profiled sheets (20, 21) viewed in cross section through the bending axes (26, 27, 31) are divided into sections (20a, 20b, 21a, 21b, 21c), with an outer profiled sheet metal section (20a, 20b) of one of the profile sheets (20) in the area of the connecting line (22, 23) an angle between 45° and 135°, preferably between 75° and 105°, more preferably between 85° and 95° and particularly preferably an angle of essentially 90° to an adjoining outer profile sheet metal section (21a, 21c) of the other of the profile sheets (21). Framework according to one of Claims 7 to 9, in which the hollow profile has a maximum cross-sectional width (24) and a maximum cross-sectional height (25), with the connecting lines (22, 23) are diagonally opposite one another in an imaginary rectangle formed from the cross-sectional width (24) and the cross-sectional height (25). Framework according to one of Claims 1 to 10, in which one of the profile sheets (21) has a partial section (21c) defined by a bending axis (31), which forms an underside of the carrier profile (13) and the width of which is smaller than a maximum cross-sectional width ( 24) of the hollow profile. Framework according to one of Claims 1 to 11, which has at least one of the further features:

- The hollow profile has a cross-sectional width (24) between 10 cm and 45 cm, preferably between 10 cm and 16 cm;

- The hollow profile has a cross-sectional height (25) between 20 cm and 90 cm, preferably between 20 cm and 32 cm;

- The profile sheet (20, 21) comprises an overhang (21d) projecting beyond the connecting line (22, 23), the extension of which is preferably between 0.5 cm and 5 cm, more preferably between 1 cm and 3 cm;

- the frame has a mast block (14) arranged in the force absorption area (16, 17) for connection to the concrete placing mast; the framework has a support system connected to the carrier profile in the force dissipation area (19a, 19b), which is designed to introduce the forces transmitted by the carrier profile into the subsoil. Framework (100), in particular according to one of the claims

1 to 12, which is designed to carry a concrete placing boom, with a support profile (13) which has at least one force absorption area (16, 17) for receiving a force flow exerted by the concrete placing boom and a force absorption area (16, 17) in the longitudinal direction. standing force dissipation area (18) for dissipating the flow of force into a subsurface, wherein the carrier profile (13) in the force absorbing area (17) has an upwardly protruding tab (40) for absorbing and forwarding at least part of the flow of force. Frame according to claim 13, which has at least one of the further features:

- The carrier profile (13) has at least two force absorption areas (16, 17) spaced apart from one another in the longitudinal direction of the carrier profile (13), the tab (40) being arranged in one of the force absorption areas (17) which is at the rear with respect to the longitudinal direction;

- The framework includes a mast (14) which is connected by means of a connecting strut (15) with the bracket (40);

- The connection between the connecting strut (15) and the bracket (40) is made by means of a bolt connection; - The tab (40) comprises an upper edge (42), the alignment of which corresponds with an angular deviation of less than 15° to an alignment of the connecting strut (15);

- An extension of the tab along a vertical axis preferably decreases in the direction of the rear end of the carrier profile (13);

- The tab is formed by a sheet metal part which is aligned substantially parallel to the longitudinal direction of the carrier profile (13);

- The carrier profile (13) comprises at least two profiled sheets (20, 21), which are folded along at least one bending axis (26, 27, 31) and assembled along at least two connecting lines (22, 23) to form a hollow profile, the tab (40) is formed as an integral part of one of the profile sheets (20, 21). Concrete pump with a framework according to one of Claims 1 to 14, a concrete pumping device and a concrete placing boom which is connected to the framework in the force absorption area (16, 17). Method for manufacturing a beam profile, with the following steps:

- Provision of at least two profile sheets,

Production of at least one fastening hole in at least one of the profile sheets, Bending the profiled sheets along a bending axis of the respective profiled sheet,

- Assembling the profile sheets into a hollow profile,

- Connecting the profile sheets along two connecting lines. Method according to claim 16 , in which the joining of the profiled sheets along the connecting lines takes place by means of welding , the fastening hole preferably being positioned such that it forms a passage to an interior region of the hollow profile after the profiled sheets ( 20 , 21 ) have been assembled .