DE102014203784A1 - Lattice boom for crawler crane, has lattice element whose longitudinal axis is oriented with working assembly, and width is greater than working assembly, so that transport of lattice element is less than maximum permissible mass - Google Patents

Abstract

The lattice boom has a case which is provided with several lattice elements (13) which are arranged in each grid along longitudinal axes (12,14) of the lattice boom main portion. The lattice elements has a grating which is arranged perpendicular to the longitudinal axis (14) of the lattice element which is oriented with a working assembly, by which the width of the lattice element is greater than the width of the working assembly, such that transport of the lattice element in working arrangement is less than maximum permissible mass.

Description

The invention relates to a lattice boom for a crane, a lattice mast element for such a lattice boom and a crane with such a lattice boom.

From the US 2009/015 9547 A1 a lattice boom crane is known. To enable ever greater payloads, a lattice boom cross-sectional area perpendicular to a lattice boom longitudinal axis can be increased. An oversized cross-section of a lattice boom, for example, with a width of more than 4 m causes problems in transporting the lattice boom.

Various approaches are known from the prior art, as individual lattice mast elements can be made divisible, foldable and / or foldable to reduce a transport volume of the lattice mast element. For example, the EP 0 609 998 A1 a longitudinally split lattice boom crane, which allows a separation of the lattice boom in a plane of symmetry such that the lattice boom with reduced height can be transported. The transfer of the lattice mast elements of a working arrangement with maximum lattice mast element volume in a transport arrangement with reduced lattice mast element volume is complex. For example, a mobile large crane with a collapsible lattice piece is also off DE 10 2006 060 347 A1 , out US 3,564,789 and from NL 1 035 078 C known.

It is the object of the present invention to provide a lattice boom having a plurality of lattice mast elements, on the one hand has a high load capacity and on the other hand is easy to transport.

This object is achieved by a lattice boom with the features specified in claim 1.

A lattice boom has a plurality, in particular detachably connectable to each other, lattice mast elements. The lattice mast elements are each arranged with a lattice mast element longitudinal axis along a lattice boom longitudinal axis one behind the other. The lattice mast element longitudinal axes are oriented parallel to each other and in particular parallel to the lattice boom longitudinal axis. Each lattice mast element has a lattice mast element width oriented perpendicular to the lattice mast element longitudinal axis, which is greater than 4 m in a work arrangement. Working arrangement means that the lattice mast elements are connected to a lattice boom together. In the work arrangement, the lattice mast elements each have a perpendicular to the lattice mast element longitudinal axis oriented cross-sectional area, which allows increased load capacity for each lattice mast element and thus for a lattice boom formed therefrom. In particular, the lattice mast element width in the work arrangement is more than 6 m and in particular up to 8 m or more. Such lattice mast elements allow an uncomplicated design of a lattice boom with increased load capacity by the lattice boom elements along the lattice boom longitudinal axis are arranged one behind the other and connected to each other. At the same time the lattice mast elements are designed such that they can be transported in the working arrangement. This means that each lattice mast element in the working arrangement has a lattice mast element volume such that permissible transport dimensions for a transport are not exceeded. According to the invention, it has thus been recognized that a lattice boom with increased load capacity can also be formed by lattice mast elements, which can be transported in the work arrangement, in particular on the road, on the rail and / or in transport containers provided for this purpose. It is therefore essential that the lattice mast is composed of a plurality of short lattice mast pieces oriented along the lattice mast element longitudinal axis, wherein the lattice mast pieces each have an increased lattice mast element width in order to enable the required load capacity. The lattice mast pieces according to the invention are wide and short. The lattice mast elements according to the invention solve the hitherto pursued so far in the prior art way of exploiting the available transport volume, that the lattice mast element length is designed maximum. The available transport volume is utilized by maximizing the size of the lattice mast element width. The other dimensions of the lattice mast element are determined in compliance with the maximum possible transport volume. The lattice mast element is transportable in the work arrangement. This means that the lattice mast element in the working arrangement and in the transport arrangement is in particular identical. In particular, disassembly, folding and / or flaps of the lattice mast element for achieving maximum permissible transport dimensions is not required. This is achieved in that the lattice mast element dimensions which are next to the lattice mast element width, in particular a lattice mast element length oriented along the lattice mast element longitudinal axis and a lattice mast element height oriented perpendicular to the lattice mast element width and lattice mast element length, are selected such that permissible transport dimensions are not exceeded. In particular, the lattice mast member length and lattice mast member height is less than the lattice mast member width. In particular, the lattice mast element length and / or the lattice mast element height are less than 4 m. Especially For example, the lattice mast member width is the largest dimension of the substantially cubic lattice mast member. Such permissible transport dimensions are specified by the selection of a transport route. For example, maximum permissible transport heights must not be exceeded in order to ensure that a road transport, in particular under bridges, is possible. In order to avoid that such road transport is not declared as an excess transport, a permissible transport width must be observed. If this transport width is exceeded, additional security measures such as escort vehicles are required. Over-wide transports are preferably allowed on German motorways only at night. In these cases, transportation is complicated and costly. Similarly, permissible transport dimensions for ship transport, for transport by rail or with aircraft are specified accordingly. The specific transport dimensions can vary depending on the transport route. In particular, it is conceivable that permissible transport dimensions change over time by corresponding legal requirements. Permitted transport dimensions can also be regulated differently in terms of territory. It is essential that the lattice mast element, without additional steps of disassembly, folding and / or folding would be required, can be easily transported. In particular, the lattice mast element length is reduced over prior lattice mast elements known in the art. The lattice tower boom is uncomplicated and robust at the same time. Upgrading and disassembling the lattice boom by means of said lattice mast elements is possible quickly and with reduced expenditure of time.

According to an advantageous embodiment, in a lattice boom each lattice mast element has a lattice mast element length oriented parallel to the lattice mast element longitudinal axis, which is smaller in the working arrangement than 4 m and in particular at most 3.5 m. The lattice mast element has an enlarged cross-sectional area oriented perpendicular to the lattice mast element longitudinal axis. At the same time, the lattice mast element length L is reduced. Such a lattice boom has wide and short lattice mast elements.

According to a further advantageous embodiment, the lattice mast elements are each designed cuboid and are in particular hollow along the lattice mast element longitudinal axis. Such a lattice mast element is designed substantially as a rectangular hollow profile. Such a lattice mast element and a lattice boom formed therefrom have a high intrinsic stability with reduced use of material. The specific gravity of such a lattice boom is reduced. Because all lattice mast elements can be made hollow, the resulting lattice boom is also hollow.

According to a further advantageous embodiment, the lattice mast element is made in one piece and has a lattice mast element frame. The lattice mast element frame is in particular indivisible and rigid. The lattice mast element has improved rigidity and stability. For example, the lattice mast element frame may have a bar structure, wherein a plurality of bars and / or tubes are welded together to the lattice mast frame. Such a bar structure may have substantially parallel to the lattice mast element longitudinal axis oriented corner tubes and diagonal bars arranged therebetween.

Alternatively, it is also conceivable to provide four, each oriented in particular parallel to the lattice mast element longitudinal axis, corner tubes, which are fixedly connected to each other, for example by welding. A lattice mast element frame formed by four corner tubes may be infilled on side surfaces, in particular by rods and / or plates.

According to a particularly preferred embodiment, at least one connecting device is provided in each case on an upper and lower or front and rear end of the lattice mast element oriented along the lattice mast element longitudinal axis. The connection device allows two lattice mast elements adjacently disposed along the lattice boom longitudinal axis to be connected. Such a connection device may, for example, be a flange welded to the lattice mast element frame and having at least one connection opening. Through such connection openings connecting elements such as screws or bolts, in particular parallel to the lattice mast element longitudinal axis, are plugged for connecting the lattice mast elements. It is also conceivable that a connecting device has connecting straps into which connecting elements in the form of bolts or screws, in particular in a plane perpendicular to the lattice mast element longitudinal axis, can be inserted.

According to a further advantageous embodiment, the lattice mast element frame has at least one stiffening element. The at least one stiffening element is arranged in a plane oriented parallel to the lattice mast element longitudinal axis. This means that the at least one stiffening element on side surfaces of the cuboid lattice mast element and in particular not on perpendicular to the lattice mast element longitudinal axis oriented top surfaces of the lattice mast element, is arranged. The stiffening element may be designed rod-shaped or plate-shaped. The stiffening elements may be fixedly connected to the lattice mast frame, for example by welding. The stiffening elements can also be detachably arranged on the lattice mast element frame, for example pluggable or bolted. This makes it possible to additionally reduce the transport weight by transporting the stiffening members separately from the lattice mast frame.

According to a further advantageous embodiment, the lattice mast element is designed in several parts. This makes it possible to move the lattice mast element starting from the working arrangement in a transport arrangement such that the required transport dimensions of the lattice mast element are further reduced. This can result in additional advantages during transport. In particular, several lattice mast elements can be transported with the same transport volume.

In a further advantageous embodiment, the lattice mast element is designed foldable. By folding the lattice mast element, a lattice mast element width in the unfolded working arrangement of the lattice mast element can be converted into a lattice mast element width in a folded transport arrangement such that the lattice mast element width in the transport arrangement is reduced. In particular, the lattice mast element width in the transport arrangement is less than 4 m and in particular at most 3 m.

According to a further advantageous embodiment, the lattice mast element comprises several along the lattice mast element width oriented, articulated interconnected components. The components are designed in particular rod-shaped, frame-shaped and / or plate-shaped. As a result of the folding, the components can each be pivoted relative to one another along a pivot axis oriented parallel to the lattice mast element longitudinal axis. As a result, the lattice mast element width can be reduced in the transport arrangement.

According to a further advantageous embodiment, the lattice mast element has a plurality of components which are releasably connected to each other. In the work arrangement, the components are firmly connected. In the transport arrangement, the components are detached from one another such that the lattice mast element width in the released transport arrangement is smaller than the lattice mast element width in the connected working arrangement. In particular, the lattice mast element width in the transport arrangement is less than 4 m and in particular at most 1 m. The required transport volume for such a lattice mast element is significantly reduced.

According to a further advantageous embodiment, the components are designed as side components that are like a frame. In particular, the side components are designed as rectangular frames. The side components are each arranged in a plane spanned by the lattice mast element width and the lattice mast element longitudinal axis. The side components are arranged parallel to each other and spaced from each other on the lattice mast element. The side components are detachably connected together.

According to a particularly advantageous embodiment, the side components by at least one rod element and / or a lacing, which may be attached in particular to the rod elements, stiffening connected to each other. Such a lacing can be for example a glass fiber lacing. A fiberglass lacing has a particularly low weight and allows a lacing with high strength.

According to a further advantageous embodiment, the lattice mast elements along the lattice mast element longitudinal axis are releasably connected to each other. In particular, this can be done by means along the lattice mast element longitudinal axis and / or perpendicular to the lattice mast element longitudinal axis oriented fasteners. As connecting elements serve for example bolts and / or screws.

According to a further advantageous embodiment, each lattice mast element has several, in particular four, corner stems. The corner handles are designed in particular as corner tubes. The respective longitudinal axes of the corner stems define corner points of a cross-sectional area of the lattice mast element oriented perpendicular to the lattice mast element longitudinal axis. The corner handles are oriented substantially along the lattice pole longitudinal axis. This ensures that the cross-sectional area along the lattice mast element longitudinal axis is constant. It may be desirable to vary the cross-sectional area along the lattice mast member longitudinal axis, for example to allow a cross-sectional transition. Such a lattice mast element is referred to as adapter lattice mast element. Such adapter elements may be disposed on a lattice boom longitudinal axis at the lower and / or upper end of the lattice boom to connect the lattice mast elements with a foot piece, which serves for pivotable articulation of the lattice boom on the crane, or on a head piece, the cable guide for a hook block serves to connect.

It is a further object of the invention to provide a lattice mast member which allows the formation of a lattice boom with increased load capacity, while facilitating transportation of the lattice mast member.

This object is achieved by a lattice mast element with the features specified in claim 15. Such a lattice mast element has, in a working arrangement, a lattice mast element width which is oriented perpendicular to the lattice mast element longitudinal axis and which is greater than 4 m, in particular greater than 6 m and in particular greater than 8 m. The lattice mast element does not exceed in the working arrangement the permissible transport dimensions for a transport. This means that the lattice mast element in the work arrangement, ie in particular without an additional transferring into the transport arrangement, is easy to transport.

The associated advantages correspond to those of the lattice boom according to the invention, to which reference is hereby made.

It is a further object of the present invention to provide a crane with a lattice boom, wherein the lattice boom has an increased carrying capacity and at the same time is easy to transport.

This object is achieved by a crane with the features specified in claim 16. Such a crane has the advantages of the lattice boom according to the invention, to which reference is hereby made.

Embodiments of the invention will be explained in more detail with reference to the drawing. In this show:

1 1 a schematic side view of a crawler crane with a lattice boom having a plurality of lattice mast elements,

2 a highly schematic view of the lattice boom according to arrow II in 1 .

3 a perspective view of a lattice mast element according to an embodiment of the invention,

4 a side view of a partial section of a lattice boom with two interconnected lattice mast elements according to 3 .

5 a 3 corresponding perspective view of a lattice mast element according to another embodiment of the invention,

6 a sectional view according to section plane VI-VI in 5 .

7 a top view of a lattice mast element in an unfolded work arrangement according to another embodiment of the invention in a plane perpendicular to the lattice mast element longitudinal axis,

8th a 7 corresponding representation of the lattice mast element in a folded transport arrangement,

9 a perspective view of a lattice mast element according to another embodiment of the invention,

10 a representation of the lattice mast element according to 9 in a transport arrangement in which components of the lattice mast element are detached from each other, and

11 a 7 corresponding representation of a lattice mast element according to a further embodiment of the invention with stiffening elements.

An in 1 illustrated crane 1 is designed as a crawler crane with two on an undercarriage 2 parallel crawler tracks 3 , Around a vertical axis of rotation 4 rotatable on the undercarriage 2 is a superstructure 5 arranged. The superstructure 5 is a horizontally arranged rocking axis 6 a lattice boom 7 in a vertical plane, the plane of the drawing in 1 corresponds, tilted hinged.

Also on the superstructure 5 around a horizontally arranged pivot axis 8th is a guy jib 9 hinged pivotally. By means of a guy rope 10 is the lattice boom 7 over the guy arm 9 guyed.

The lattice boom 7 includes a foot piece 11 with which the lattice boom 7 swiveling on the luffing axis 6 on the superstructure 5 of the crane 1 is articulated. The foot piece 11 is in the drawing plane according to 1 V-shaped.

Along a lattice boom boom longitudinal axis 12 close to the foot piece 11 several lattice mast elements 13 at. The lattice mast elements 13 are along the lattice boom longitudinal axis 12 detachably connected to each other. The lattice mast elements 13 each have a lattice mast element longitudinal axis 14 on, parallel to the lattice boom longitudinal axis 12 is oriented. In the illustration according to 1 fall the respective lattice pole longitudinal axes 14 with the lattice boom boom longitudinal axis 12 together. At one of the foot piece 11 opposite end of the lattice boom 7 is a head piece 15 intended. The head piece 15 serves for cable guidance, in particular for one on the head piece 15 attached hook bottle 16 , The hook bottle 16 serves to lift and hold loads.

The lattice mast elements 13 each have a lattice mast height H, which is substantially for all lattice mast elements 13 is identical. The lattice mast height H may be for individual lattice mast elements 13 along the lattice boom longitudinal axis 12 vary. The lattice mast height H is, for example, at most 3.2 m. The lattice mast element height H is perpendicular to the lattice mast element longitudinal axis 14 oriented. The lattice mast element height H is in particular parallel to the plane of the drawing 1 aligned.

The lattice mast elements 13 are each cuboid and have a along the lattice mast element longitudinal axis 14 oriented lattice mast element length L on. The lattice mast element length L in the working arrangement is less than 4 m and in particular at most 3.5 m. The lattice mast element length is especially for all lattice mast elements 13 identical. The lattice mast element length L can be used for different lattice mast elements 13 vary.

In 2 is the lattice boom 7 according to 1 shown schematically. For the sake of clarity, other components of the crane 1 , in particular the crane undercarriage 2 , the crane superstructure 5 , the guy jib 9 and the hook bottle 16 , not shown.

The representation of the lattice boom 7 corresponds essentially to the representation in 1 , wherein the plane of the drawing is 90 ° with respect to the lattice boom longitudinal axis 12 is turned. According to the view in 2 it becomes clear that the lattice mast elements 13 a lattice mast element width B which is increased relative to the lattice mast element length L and in particular to the lattice mast element height H. According to the embodiment shown, the lattice mast element width B in the working arrangement is according to FIG 2 8 m. In particular, the lattice boom according to the invention enables a lattice mast element width B in the working arrangement of the lattice mast element 13 more than 4 m, in particular more than 6 m. Such lattice tower element widths B of more than 4 m are usually feasible only with increased effort. An increased effort, for example, is that the lattice mast elements are designed divisible, foldable and / or foldable to the required in the work arrangement lattice mast element width B for transport of the lattice mast element 13 to reduce. Otherwise, a transport of such a lattice mast element according to the prior art would not be possible. Due to the fact that the lattice mast elements according to the invention 13 have a reduced lattice mast element length L, which is in particular smaller than 4 m and in particular at most 3.5 m, is a permissible transport volume for the lattice mast element 13 below. This means that such a lattice mast element 13 in the working arrangement, so that no additional disassembly, folding and / or flaps would be required, can be transported directly. In particular, a transport on the road, on the rail and in designated transport containers is possible. It has therefore been recognized that the framework conditions predetermined by a maximum permissible transport volume can advantageously be exploited in that an increased lattice mast element width is possible if a lattice mast element length L is reduced. The reduction of the lattice mast element length L is unproblematic, as by a series arrangement along the lattice boom longitudinal axis 12 of several lattice mast elements 13 a desired total length L _{ges of} the lattice boom 7 is specifically adjustable. The design of the lattice boom 7 with a desired overall length L _tot and with a desired cross-sectional area for a required load-bearing capacity perpendicular to the lattice boom longitudinal axis 12 oriented cross-sectional area is possible. The perpendicular to the lattice boom boom longitudinal axis 12 Oriented cross-sectional area is defined by the lattice mast member width B and the lattice mast height H.

The following is based on 3 and 4 the lattice mast element 13 explained in more detail according to an embodiment. The lattice mast element 13 has a one-piece lattice mast frame. The lattice tower frame comprises four each parallel to the lattice pole longitudinal axis 14 oriented corner pipes 17 , The corner pipes 17 are each executed in particular hollow. The four corner pipes 17 clamp the cuboid shape of the lattice mast element 13 on. At each lower end are two adjacent corner pipes 17 by each perpendicular to the lattice mast element longitudinal axis 14 oriented cross tubes 18 firmly connected. The pipes 17 . 18 are in particular welded together. At one upper end of the Eckerohre 17 are no cross tubes 18 intended. The lattice mast element frame of the lattice mast element 13 is open at the top.

For a stiffening of the lattice mast element frame are between each two adjacent corner pipes 17 several, each diagonally arranged stiffening elements 19 provided in the form of stiffening tubes. The stiffening tubes 19 are each firmly connected to each other, in particular by welding. In addition, the Aussteifungsrohre 19 on the cross tubes 18 and / or on the corner pipes 17 attached, in particular welded. The lattice mast element frame formed thereby is indivisible and rigid. The lattice mast frame has a high stability. The corner tubes each face the front 17 Connecting devices on. The connecting devices are thus each at an upper and lower end along the lattice mast element longitudinal axis 14 on the lattice mast element 13 oriented. The connection devices 20 are designed as multi-lobed connecting straps. According to the embodiment shown in FIG 4 is a lower connection device 20 designed as a three-lice connecting strap. Accordingly, an in 4 Connecting device shown above 20 of the lattice mast element 13 designed as a two-lice connection tab. This makes it possible for two adjacent lattice mast elements 13 particularly uncomplicated can be connected together by a lower, three-lice connection device of a lattice mast element with an upper, two-lice connection device of a lower lattice mast element 13 corresponds. The connection of the lattice mast elements 13 together takes place in that a connecting element, in particular a locking pin 21 , in aligned openings of the connecting straps 20 is plugged. As in 4 can also be shown at each upper ends of the stiffening tubes 19 and on a side facing away from the underside of the transverse tubes 18 Connecting devices may be provided in the form of multi-lobed connection devices. The connecting elements 21 for connecting two adjacent lattice mast elements 13 are in a common connection plane 22 arranged. The connection level 22 is perpendicular to the respective lattice mast element longitudinal axis 14 the lattice mast elements to be joined together 13 oriented. The connection level 22 is perpendicular to the lattice boom longitudinal axis 12 oriented.

The following is based on 5 and 6 a further embodiment of the invention described in more detail. The lattice mast element 23 includes four corner pipes 17 parallel to the lattice pole longitudinal axis 14 are oriented. The corner pipes 17 are by a frontal top and bottom of the corner tubes 17 attached flange attachment 24 firmly connected. In particular, the corner tubes 17 each end face with the flange attachments 24 welded. As a result, the lattice mast element 23 a one-piece, in particular indivisible and rigid, lattice mast frame on.

The two flange attachments 24 are essentially identical. The flange attachment 24 comprises four substantially annular corner tube flanges 25 and two adjacent corner tube flanges 25 interconnecting transverse flanges 26 , The flange attachment 24 comprises flat belts which are in a plane perpendicular to the lattice mast element longitudinal axis 14 are arranged. The bands point along the lattice pole longitudinal axis 14 oriented through holes 27 on. The through holes 27 , which are located in lateral protruding sections of the flange attachment 24 are arranged, serve for the insertion of fasteners 21 for connecting two adjacently arranged lattice mast elements 23 , To infill the lattice tower element 23 can improve between two adjacent corner pipes 17 , as in 5 and 6 indicated, plate-shaped stiffening elements 28 be provided. Such stiffening plates 28 are made in particular of steel. It is possible to have on one or more side surfaces of the lattice mast element 23 instead of or in addition to a steel plate 28 to use one or more stiffening tubes. The bracing plates 28 are in particular detachable with the lattice mast element frame of the lattice mast element 23 connected. In particular, the steel plates 28 bolted to the lattice tower frame. It is also conceivable that the steel plates 28 in designated grooves on the corner pipes 17 are plugged. The steel plates 28 can also with the corner pipes 17 welded and / or riveted. It is conceivable that the transverse flanges 26 in one piece with the steel plates 28 are executed.

Instead of a screw as a connecting element 21 are also plug pins conceivable. The connecting elements 21 are at the lattice mast elements 23 each parallel to the lattice pole longitudinal axis 14 , ie parallel to the lattice boom longitudinal axis 12 , oriented.

The following is based on 7 and 8th a further embodiment of the invention explained in more detail. The lattice mast element 29 is in each case in a direction perpendicular to the lattice boom longitudinal axis 12 oriented level. The lattice mast element 29 differs from the previous embodiments essentially in that the lattice mast element 29 is executed in several parts. The lattice mast element 29 is foldable. In an unfolded working arrangement, the lattice mast element 29 a lattice mast element width B _A , which is for example 8 m. By folding is the lattice mast element 29 in an in 8th illustrated, folded transport arrangement can be transferred. In the transport arrangement, the lattice mast element 29 a lattice mast member width B _T which is smaller than the lattice mast member width B _A in the unfolded work arrangement according to FIG 7 , The lattice mast element width B _T in the folded transport arrangement is in particular smaller than 4 m and in particular is at most 3 m.

The folding is made possible in that in a direction along the lattice mast element width B, several, each articulated components 30 are provided. The pivoting is about a respective two adjacent components 30 pivotally interconnecting pivot axis 31 given. The pivot axis 31 is in each case parallel to the lattice mast element longitudinal axis 14 oriented. In particular, it is conceivable, in each case two components 30 to connect to a hinge, especially in the form of a piano band. Such a piano band is in particular a pivoting angle of a maximum of 180 °, as in 7 shown when the components 30 along the lattice mast width B are limited.

This in 7 and 8th illustrated lattice mast element 29 each includes two such hinges along the lattice pole width B 32 , The hinges 32 are each between a corner tube 17 and one between the corner pipes 17 arranged center tube 33 arranged and connected to each pivotally. Neighboring corner pipes 17 and center tubes 33 are each in pairs by means of a stiffening frame 34 for example, two the respective tubes 17 respectively. 33 interconnecting cross tubes 18 can have.

To avoid the lattice mast element 29 is folded in an unintentional manner in the work arrangement, at least portions of the lattice mast element are stiffened in the working arrangement. In the lattice mast element 29 Regarding the center tubes 33 connecting cross tube 18 is formed symmetrically, is an in 7 left section of the lattice mast element 29 by means of a stiffening frame 35 secured. The stiffening frame 35 has in the plane perpendicular to the lattice mast element longitudinal axis 14 a rectangular shape with a diagonal bar connecting two opposite corners of the rectangle. The stiffening frame 35 is at the corner pipes 17 , the cross tubes 18 , the center pipes 33 and / or the hinges 32 releasably secured. The geometry of the stiffening frame 35 , in particular its outer contour, is designed such that a folding of the lattice mast element 29 is blocked.

At the in 7 Right part of the lattice mast element shown 29 Folding is prevented by having a spacer bar 36 between two opposing hinges 32 is arranged. The distance bar 36 For example, on the two hinges 32 be plugged each. The distance bar 36 prevents the hinges 32 each to move towards each other. A pivoting of the hinges 32 and thus a foldability of the lattice mast element 29 are prevented. It is conceivable, instead of the distance bar 36 to use a deviating spacer element to the pivoting of the hinges 32 to block. For example, a spacer plate can be used, which is opposite the spacer bar 36 along the lattice pole longitudinal axis 14 has an increased length. In order to achieve a sufficient transverse stability, ie in a direction parallel to the lattice mast element width B, are diagonal cabling 37 intended. Such a wiring 37 for example, connects a corner pipe 17 with a diagonally opposite tube of the hinge 32 , The pipe of the hinge 32 Again, with a diagonally opposite center tube 33 wired.

The following is a folding operation of the lattice mast element 29 starting from the in 7 illustrated work arrangement explained. First, the stiffening frame 35 , the distance rod 36 as well as the cabling 37 on the lattice mast element 29 away. That's the hinges 32 free. The fact that a maximum swing angle of 180 ° is specified, it is impossible that the hinges 32 with the components 30 to the outside, so two opposing hinges 32 away from each other, panning. In particular, by an operation, the hinges 32 be pivoted towards each other, so that the components 30 to fold each other. The pivot axes 31 from opposite hinges 32 are approximated to each other. The components 30 form on the hinge 32 a V shape. In this arrangement, the lattice mast element 29 as in 8th transported transported. The lattice mast element width B _T reduced in the transport arrangement is smaller than the maximum lattice mast element width B _A in the work arrangement. Optionally, securing means (not shown) may be used to prevent during transport of the lattice mast element 29 an unfolding of the lattice mast element, in particular of the hinges 32 , is prevented.

The following is based on the 9 and 10 a further embodiment of the invention described. The lattice mast element 38 is as well as the lattice mast element 29 executed in several parts. The lattice mast element 38 has two spaced-apart side components 39 on. The side components 39 are arranged in one of the lattice mast element width B and one of the lattice mast element length L spanned plane. The side components are each frame-like and in particular designed in one piece. The frame-like side components 39 are by two infill bars 40 connected and stiffened. The infill rods 40 are each designed as a rod element. In addition, a lacing 41 provided in the form of a glass fiber lacing. To the Ausfachungsstäbe 40 with the side components 39 in appropriate to be able to tie, are at the Ausfachungsstäben 40 each welded fastening eyes 42 provided, to which the lacing 41 can be attached. It is also conceivable that an overall lacing 41 is provided, which is passed through the respective fastening eyes. In this case, the lacing is 41 executed in one piece.

For a transport of the lattice mast element 38 can the lacing 41 be solved. In addition, the infill rods can 40 between the page components are removed. In this case, the two side components 39 space-saving on each other, as in 10 indicated, arranged, the Ausfachungsstäbe 40 can on the frame-like side components 39 be arranged. In such a transport arrangement, the lattice mast element height H _{T is} significantly reduced compared to the lattice mast element height H _A in the working arrangement according to FIG 9 , In particular, the lattice mast element height in the transport arrangement is less than 1 m. In contrast, the lattice mast element width B and the lattice mast element length L remain unchanged between the work arrangement and the transport arrangement.

The following is based on the 11 a further embodiment of the invention described. The lattice mast element 43 is made in one piece. The lattice mast element 43 has four corner pipes 17 and the corner pipes 17 interconnecting cross tubes 18 on. In particular, between two adjacent corner pipes 17 two transverse tubes each 18 along the lattice pole longitudinal axis 14 spaced apart from each other. According to the embodiment shown, the lattice mast element 43 a lattice mast width B and a lattice mast height H which are substantially identical. The lattice mast element 43 has a perpendicular to the lattice mast element longitudinal axis 14 oriented cross-sectional area that is substantially square. The cross-sectional area can also be rectangular.

The lattice mast element 43 has stiffening elements 44 on. According to the embodiment shown, the stiffening elements 44 designed as stiffening tubes. The stiffening tubes are each approximately centered on fasteners 45 with the cross tubes 18 connected. In particular, the stiffening tubes with the fastening elements 45 bolted. Provided bolts are parallel to the lattice mast element longitudinal axis 14 oriented. The stiffening elements 44 are in one of the corner pipes 17 and the cross tubes 18 arranged frame arranged. The stiffening elements 44 are diamond-shaped relative to the lattice mast element longitudinal axis 14 oriented. The lattice mast element 43 has an increased rigidity.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 2009/0159547 A1 [0002]
• EP 0609998 A1 [0003]
• DE 102006060347 A1 [0003]
• US 3564789 [0003]
• NL 1035078 C [0003]

Claims (16)

Lattice boom ( 7 ) for a crane ( 1 ) comprising a plurality of each with a lattice mast element longitudinal axis ( 14 ) along a lattice boom longitudinal axis ( 12 ) arranged behind one another lattice mast elements ( 13 ; 23 ; 29 ; 38 ; 43 ), where a. each lattice mast element ( 13 ; 23 ; 29 ; 38 ; 43 ) a perpendicular to the lattice mast element longitudinal axis ( 14 ) oriented lattice mast member width (B), which is greater than 4 m in a work arrangement, and b. each lattice mast element ( 13 ; 23 ; 29 ; 38 ; 43 ) in the work arrangement for transporting the lattice mast element ( 13 ; 23 ; 29 ; 38 ; 43 ) falls below the maximum permissible limits. Lattice boom according to claim 1, characterized in that each lattice mast element ( 13 ; 23 ; 29 ; 38 ; 43 ) a parallel to the lattice mast element longitudinal axis ( 14 ) oriented lattice mast element length (L) which is less than 4 m in the working arrangement and in particular at most 3.5 m. Lattice boom according to one of the preceding claims, characterized in that the lattice mast element ( 13 ; 23 ; 29 ; 38 ; 43 ) cuboid, in particular along the lattice mast element longitudinal axis ( 14 ) hollow, is executed. Lattice boom according to one of the preceding claims, characterized in that the lattice mast element ( 13 ; 23 ) has a one-piece, in particular indivisible and rigid, lattice mast element frame. Lattice boom according to claim 4, characterized in that the lattice mast element ( 13 ; 23 ) on one each along the lattice pole longitudinal axis ( 14 ) oriented upper and lower end at least one connecting device ( 20 ; 24 ) for connection to a longitudinal axis along the lattice boom ( 12 ) adjacent lattice mast element ( 13 ; 23 ). Lattice boom according to claim 4 or 5, characterized in that on the lattice mast element frame at least one in a parallel to the lattice mast element longitudinal axis ( 14 ) oriented plane arranged, in particular rigid, stiffening element ( 19 ; 28 ) for additional stiffening of the lattice mast element ( 13 ; 23 ) is provided. Lattice boom according to one of claims 1 to 3, characterized in that the lattice mast element ( 29 ; 38 ) is executed in several parts. Lattice boom according to claim 7, characterized in that the lattice mast element ( 29 ) is foldable such that the lattice mast element width (B _T ) in a folded transport arrangement is smaller than the lattice mast element width (B _A ) in the unfolded working arrangement of the lattice mast element (FIG. 29 ). Lattice boom according to claim 7 or 8, characterized in that the lattice mast element ( 29 ) a plurality of articulated interconnected components (B) along the length of the lattice pole (B) 30 ) having. Lattice boom according to claim 7, characterized in that the lattice mast element ( 38 ) several components ( 39 . 40 . 41 ) which are interconnected in the work arrangement and are disengaged from one another in a transport arrangement such that the lattice mast element height (H _T ) in the released transport arrangement is smaller than the lattice mast element height (H _A ) in the connected work arrangement. Lattice boom according to claim 10, characterized in that the lattice mast element ( 38 ) two spaced apart, each in one of the lattice mast member width (B) and the lattice mast member longitudinal axis ( 14 ) spanned level arranged side components ( 39 ), which are executed like a frame. Lattice boom according to claim 11, characterized in that the side components ( 39 ) by at least one rod element ( 40 ) and / or a lacing ( 41 ) are stiffening interconnected. Lattice boom according to one of the preceding claims, characterized in that the lattice mast elements ( 13 ; 23 ; 29 ; 38 ; 43 ) along the lattice boom longitudinal axis ( 12 ) are releasably connected to each other, in particular by means of along and / or perpendicular to the lattice boom longitudinal axis ( 12 ) oriented fasteners ( 21 ). Lattice boom according to one of the preceding claims, characterized in that the lattice mast elements ( 13 ; 23 ; 29 ; 38 ; 43 ) a plurality, in particular four, corner tubes ( 19 ), the corner points of a perpendicular to the lattice mast element longitudinal axis ( 14 ) oriented cross-sectional area, wherein the corner tubes ( 19 ) substantially along, in particular parallel to, the lattice mast element longitudinal axis ( 14 ) are oriented. Lattice mast element ( 13 ; 23 ; 29 ; 38 ; 43 ) for a lattice boom ( 7 ) according to any one of the preceding claims. Crane ( 1 ) with a lattice boom ( 7 ) according to one of claims 1 to 14.

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