DE202020101369U1 - Beam crane made of a wood-based material - Google Patents

Abstract

Beam crane comprising - at least one beam (1, 2), which beam (1, 2) extends in a longitudinal direction of the beam and which beam (1, 2) has a beam cross section designed as a full cross section, - at least one arranged on the beam (1, 2) Rail (15), on which rail (15) a trolley (7) is mounted, characterized in that the beam (1, 2) is made of a wood-based material.

Description

The invention relates to a gantry crane according to the preamble of claim 1.

EP2942317 describes a girder crane, in which girder crane the axis of inertia of the support for receiving the trolley and the axis of inertia of a beam cross-section are arranged congruently. EP2942317 also does not disclose the production of the beam cross-section from a wood material.

EP0051270A2 describes a truss crane, which truss crane has no recess for receiving a rail, on which rail a trolley can be stored.

The invention disclosed here addresses the technical problem of producing a sustainable girder crane, which girder crane also has advantageous properties when heated. The gantry crane should also have the lowest possible height.

This task is solved according to the invention by claim 1.

The term wood-based material encompasses all materials which are produced using wood or using wood fibers or using the raw material wood according to known processes. The person skilled in the art knows techniques as to how the person skilled in the art can combine the wood fibers or how the person skilled in the art can combine wooden elements to form a static element. The person skilled in the art is able to combine a wood material with its material properties that are advantageous for solving a technical problem with a further material with further material properties that are further advantageous for solving a technical problem. The person skilled in the art can in particular combine the material wood with other organic substances to produce a sustainable material, which sustainable material can be used in the gantry crane according to the invention.

For example, the beam can be made from glue carriers, which glue carriers comprise glued wooden slats. The bar can also be made from glued pieces of wood of different sizes, such as chips and / or strains and / or veneers. The formation of two cross-sectional partial areas with different widths is advantageously suitable for forming the first cross-sectional partial area from a first glue carrier and the formation of the second cross-sectional partial area from a second glue carrier, the glue carriers also being connected in the sense of the composite of the cross-sectional partial areas.

The formation of the cross-sectional partial areas from wooden workpieces is advantageous in the case of a temperature load which varies over time, since wooden workpieces generally have a high heat storage capacity and thus react very slowly to temperature fluctuations. When the cross-sectional partial areas are formed from solid wooden workpieces, this advantageous effect, which is based on the thermal property of wooden workpieces, is particularly important since larger, thermally inert reacting masses are heated.

Compared to the otherwise usual steel beam cranes, the beam crane according to the invention made of a wood material has the advantage that the wood material does not become soft when the element that is subjected to static or dynamic loads is heated, i.e. that the modulus of elasticity of the wood-based material remains essentially constant. The beam crane according to the invention is characterized in that the load-bearing capacity is retained when the beams are heated. This can be advantageous, for example, when the girder crane according to the invention is used in a production workshop with local heat sources or in the event of a fire.

The material wood has advantageous properties under dynamic loads.

The cross-sectional partial areas can thus be designed as solid cross-sections, full cross-sections and / or in the form of a profile such as, for example, a box shape, a U-profile, C-profile or I-profile.

The beam crane can be characterized in that a first vertical axis of inertia of the first cross-sectional partial area and a second vertical axis of inertia of the second beam cross-section are spaced apart.

The spacing of the vertical axes of inertia poses no technical challenge for the person skilled in the art, particularly when the cross-sectional partial areas are designed as solid wooden elements. The cross-sectional partial areas have a sufficiently large cross-section and / or a sufficiently large width to accommodate the cutting moments.

The person skilled in the art can nevertheless strive to design the cross-sectional partial areas in such a way that the vertical axes of inertia are as small as possible from one another. The person skilled in the art tries to implement the latter in particular if the cross-sectional partial areas are designed as non-solid elements such as, for example, hollow boxes. However, it should be noted here that the use of hollow box cross sections is less advantageous in the event of a fire, since a hollow box shape of a beam, compared to a solid beam, has a smaller volume that can be burned off while maintaining the load-bearing capacity of the beam crane than a solid cross section.

In the girder crane according to the invention, the first cross-sectional partial area can be arranged above the second cross-sectional partial area. This arrangement of the first cross-sectional partial area and the second cross-sectional partial area is advantageous with regard to the arrangement of the rail in the beam cross-section and the absorption of the forces introduced into the beam cross-section via the rail.

It is furthermore advantageous if the static and dynamic forces introduced via the rail are introduced into the second cross-sectional partial area, which second cross-sectional partial area has a greater width than the first cross-sectional partial area.

The trolley can be arranged in an area between the two beams - also referred to as a double-girder overhead traveling crane. The trolley guided between the beams is movably supported on both sides by means of rails on the beams parallel to the longitudinal direction of the beams. The rails arranged on the individual beams extend parallel to one another and in each case parallel to the longitudinal direction of the beams.

The recess can advantageously be arranged in the bar on the side of the bar facing the further bar. This advantageous arrangement is also shown in the figures.

The two beams can be connected by a cross-connection, which cross-connection is connected to the first cross-section of the beam.

Due to the spacing of the vertical axes of inertia, a cutting moment can arise in the cross-section of the beam, which is due to the eccentric introduction of forces into the rail relative to the axis of inertia of the respective cross-sectional partial area, which rail is spaced from at least one vertical axis of inertia. The cross bond can cause these cutting moments to be absorbed.

The cross composite can be arranged at an angle of 90 ° or at an angle deviating from 90 ° to the longitudinal direction of the beams.

The cross composite can be arranged at an angle of 90 ° to the longitudinal direction of the beams. The cross composite can also be formed at an angle deviating from 90 ° to the longitudinal direction of the beams and thus as a diagonal.

The beams can be connected by a plurality of cross assemblies, the cross assemblies arranged at the ends of the beams being arranged, for example, at an angle of 90 °. The further cross assemblies can extend as a so-called diagonal between the beams, which diagonals, for example and in no way restrictively, have an angle of 45 ° to the longitudinal direction of the beams.

The cross-connection can be connected to the top of the first cross-sectional partial area. In an advantageous manner, the cross-connection can be detachably connected to the upper side of the first cross-sectional partial area, in order to thereby obtain a simple possibility of pulling to the trolley arranged under the cross-connection.

The cross-section of the beam can be made from glued wooden slats, two wooden slats each having an adhesive joint, an adhesive joint being arranged in the contact area between the first cross-sectional partial area and the second cross-sectional partial area.

Shear forces can occur in the contact area between the first cross-sectional partial area and the second cross-sectional partial area, which shear forces are advantageously absorbed via an adhesive joint. According to the prior art, an adhesive joint can have a higher strength, in particular a higher shear strength, than a wood material. The person skilled in the art can use these advantageous properties of the adhesive joint by arranging an adhesive joint in this heavily loaded part of the cross-section of the beam.

That area of the wooden workpiece can also be included in the adhesive joint, in which area the adhesive penetrated during the manufacture of the adhesive joint and in the same place assigns higher strength properties to the wooden material. The person skilled in the art can use adhesive techniques or methods for producing the adhesive joint or methods for processing adhesives or adhesives according to the prior art, by means of which methods or which adhesives a deep penetration into the wooden workpiece is permitted.

The person skilled in the art can choose the slat thickness so that in high-stressed partial areas of the girder crane the relevant partial area of the wood-based material is penetrated entirely or with an adapted portion with adhesive. Referring to the current teaching, by penetrating the Wood material with adhesive can increase the strength of the wood material.

The person skilled in the art can provide reinforcement of the beam section in order to increase the load-bearing capacity of the beam. The reinforcement can be arranged in the interior of the beam, for example in the adhesive joint between the slats or on the outer surfaces of the beam. The person skilled in the art can, for example, use textile reinforcement elements for reinforcing wood materials.

The person skilled in the art can provide a wood-based material with a higher strength than in other partial areas in highly stressed partial areas. For example, a person skilled in the art can provide a bookwood or a bamboo in the area of the transition between the first cross-section of the beam and the second cross-section of the beam. Likewise, the person skilled in the art can arrange such a heavy-duty wooden workpiece in the area of the rail.

According to the current teaching, a beam is subject to vibration. The manufacture of a girder crane from a wood-based material as defined above is advantageous because of the behavior of wood with a vibration behavior. In particular, the vibration-damping property of wood is advantageous when wood is used as the material for producing a girder crane.

Main cutting forces in the cross-section of the beam can be determined using the current teaching. To avoid shear forces in a partial area of the wooden workpiece, which partial area adjoins an adhesive joint, the person skilled in the art can provide an orientation of the adhesive joint at an angle of approximately 90 ° to a main beam cutting force.

It is hereby achieved that the adhesive joint and thus this sub-area is loaded exclusively by a tensile force and a compressive force. Those skilled in the art know that the occurrence of a compressive force as a cutting force can be more advantageous than the occurrence of a tensile force as a cutting force.

The first cross-sectional partial area can be prestressed against the second cross-sectional partial areas at least during the manufacture of the beam. The prestress is achieved by pressing the first cross-sectional partial area against the second cross-sectional partial area.

The person skilled in the art can ensure this by at least one screw, which screw extends between the first cross-sectional partial area and the second cross-sectional partial area. The at least one screw can be used to produce the adhesive pressure required to produce an adhesive bond between the first cross-sectional partial area and the second cross-sectional partial area.

By means of this screw, the bond between the first cross-sectional partial area and the second cross-sectional partial area can also be made sufficiently firm for the transmission of the cutting forces that occur. The person skilled in the art can glue the screw in the wood-based material by means of an adhesive and thus achieve the occurrence of local stress peaks at the transition between the wood-based material and the screw embedded in the wood-based material. By gluing the screw, loosening of the screw due to vibration loading of the crane can also be prevented. The person skilled in the art knows that such a vibration load is a relevant problem for cranes.

A person skilled in the art can also use a screw with a first thread and a second thread, the first thread being introduced into the first cross-sectional partial area and the second thread into the second cross-sectional partial area when the screw is inserted, thus ensuring that the cross-sectional partial areas are pressed together.

The person skilled in the art particularly arranges a screw in that beam area, which beam area is stressed by tensile cutting forces transverse to the grain of the wood-based materials. The person skilled in the art can compensate for the tensile cutting forces transverse to the fiber direction of the wood material by means of the pretension that can be achieved by means of a screw, and thus prevent the wood material from failing.

A screw in a cross-section of a beam may be sufficient to transmit cutting shear forces. To forward cutting moments, the person skilled in the art can provide at least one screw arranged in the bending tensile zone in a beam cross-section, by means of which screw the tensile cutting forces resulting from the bending moment can be absorbed.

The person skilled in the art can also provide further elements according to the prior art for transmitting the shear forces between the first cross-sectional partial area and the second cross-sectional partial area.

According to current teaching, a distinction is made between the dead load of a static component and the load, with which dead load and load the static component can be loaded. The beam crane according to the invention can be dimensioned such that the second cross-sectional partial area for the removal of the Own load and, if applicable, payload is adequately dimensioned.

According to the relevant standards, the volume of wooden beams has to be taken into account, which volumes can be destroyed in the event of a fire while maintaining the required load-bearing capacity and are not considered load-bearing elements. Since the first cross-sectional partial area has a smaller first width than the second cross-sectional partial area with the second width, the first cross-sectional partial area cannot be regarded as a load-bearing element in the event of a fire. The dead weight is only deducted from the second cross-sectional area.

The first cross-sectional partial area can be provided with a fire protection agent.

The second cross-sectional partial area can be provided with a fire protection agent.

Surface partial areas of the cross-sectional partial areas can be clad with a flame-retardant wood-based material such as hardwood or HDF, while the further cross-sectional partial areas can be produced from a soft wood such as spruce or fir.

The person skilled in the art can select the wood material from which wood material the cross-sectional partial areas are made, depending on the requirements for the gantry crane in the event of a fire.

The beams can be mounted on head carriers.

The head supports can be arranged at right angles to the longitudinal direction of the beams and can be movably mounted. The latter allows the beam crane to move in a direction transverse to the longitudinal direction of the beam.

The above-mentioned cross-connection, which cross-connection connects the beams to one another, ensures that the beams remain at a constant distance from one another when the beam crane is moving. This cross-connection can also dampen vibrations.

The beam can be connected to the head girder via a stiffening element,
which stiffening element is connected to the second cross-sectional partial area.

The stiffening element serves to transfer the forces which arise from a positive or negative acceleration of the trolley or the girder crane. The stiffening element can be connected to the second cross-sectional partial area via the second height.

• 1 zeigt eine Ansicht eines Querschnittes einer möglichen Ausführungsform des erfindungsgemäßen Balkenkrans mit zwei Balken.
• 2 zeigt ein Detail der in 1 dargestellten Ansicht des Querschnittes.
• 3 zeigt eine Ansicht von oben des in 1 und 2 dargestellten Balkenkrans.
• 4 zeigt eine Seitenansicht des in 1 und 2 dargestellten Balkenkrans.
• 5 zeigt eine weitere Ausführungsform des erfindungsgemäßen Balkenkrans mit einem Balken.
• 6 zeigt eine weitere Ausführungsform des erfindungsgemäßen Balkenkrans mit zwei Balken.
• 7 zeigt eine weitere Ausführungsform des erfindungsgemäßen Balkenkrans mit einem Balken.

The invention is additionally explained on the basis of the following embodiments shown in the figures:

• 1 shows a view of a cross section of a possible embodiment of the girder crane according to the invention with two beams.
• 2nd shows a detail of the in 1 illustrated view of the cross section.
• 3rd shows a top view of the in 1 and 2nd shown beam crane.
• 4th shows a side view of the in 1 and 2nd shown beam crane.
• 5 shows a further embodiment of the beam crane according to the invention with a beam.
• 6 shows a further embodiment of the girder crane according to the invention with two beams.
• 7 shows a further embodiment of the beam crane according to the invention with a beam.

The embodiments shown in the figures only show possible embodiments, it being noted at this point that the invention is not restricted to these specially illustrated embodiment variants, but also combinations of the individual embodiment variants with one another and a combination of an embodiment with the general description given above are possible . These further possible combinations do not have to be mentioned explicitly, since these further possible combinations are based on the teaching of technical action by means of the present invention in the ability of the person skilled in the art in this technical field.

The scope of protection is determined by the claims. However, the description and drawings are to be used to interpret the claims. Individual features or combinations of features from the different embodiments shown and described can represent independent inventive solutions. The object on which the independent inventive solutions are based can be found in the description.

1

Balken

2

Balken

3

erster Querschnittsteilbereich

4

zweiter Querschnittsteilbereich

5

Ausnehmung

6

Laufrad oder Laufräder Laufkatze

7

Laufkatze

8

Balkenaußenseitenoberfläche

9

erste vertikale Trägheitsachse

10

zweite vertikale Trägheitsachse

11

Querverbund

12

Schraube

13

Kopfträger

14

Aussteifungselement

15

Schiene

16

Kante Aussteifungselement

17

erste Breite

18

zweite Breite

19

erste Höhe

20

zweite Höhe

In the figures, the following elements are identified by the preceding reference symbols:

1

bar

2nd

bar

3rd

first cross section

4th

second cross section

5

Recess

6

Impeller or impeller trolley

7

Trolley

8th

Beam outside surface

9

first vertical axis of inertia

10th

second vertical axis of inertia

11

Cross-connection

12th

screw

13

Head carrier

14

Stiffening element

15

rail

16

Edge stiffening element

17th

first width

18th

second width

19th

first height

20th

second height

1 shows a view of a cross section of a possible embodiment of a girder crane according to the invention.

The girder crane comprises two beams 1 , 2nd . There is a special case that both the left bar 2nd as well as the right bar 1 a beam cross-section with a first cross-sectional partial area 3rd and a second cross-sectional partial area 4th exhibit. Both bars 1 , 2nd each include one on the inside of the beams 1 , 2nd arranged recess 5 to hold a rail 15 . It's on the rails 15 a trolley 7 stored which trolley 7 in the longitudinal direction of the bars 1 , 2nd and so normal to the image plane of the 1 and the 2nd is movable.

As an alternative to the formation of both bars 1 , 2nd with a recess 5 it is also conceivable that only one bar 1 , 2nd from a first cross section 3rd with a first width 17th and a second cross-sectional partial area 4th with a second width 18th is made, the bar 1 , 2nd a recess 5 to hold the rail 15 includes. The further bar can have any cross-sectional shape.

To maintain clarity, in 1 only the bars 1 , 2nd who have favourited Trolley 7 and the head carrier 13 identified by reference numerals.

The beam crane according to the invention comprises at least one beam 1 with a first cross section 3rd and a second cross-sectional partial area 4th how these cross-sectional subsections 3rd , 4th are described in the following discussion.

The beam crane according to the invention can be a further beam 2nd include at least one bar 1 , 2 a first cross-sectional partial area 3rd and a second cross section 4th according to the disclosure. With two bars 1 , 2nd can the gantry crane according to the invention a cross composite 11 exhibit. The bars can also 1 , 2nd on head straps 13 be stored.

The 1 and the 2nd show the embodiment of the girder crane according to the invention, which embodiment the inventor will most frequently implement in the future, the latter in no way to be regarded as a deposition of the other possible embodiments.

It will be further discussed in the 2nd included detailed view of the bar 1 referred. Those skilled in the art will recognize that all of the following comments on the right bar 1 also - but not mandatory - on the left bar 2nd are applicable.

The bar 1 or the bar cross section of the bar 1 comprises a first cross-sectional partial area 3rd and a second cross section 4th which cross-sectional areas 3rd , 4th a first width 17th and first height 19th or a second width 18th and second height 20th exhibit. The first width is advantageous 17th less than the second width 18th so that a recess 5 to hold one rail and one wheel or several wheels 6 a trolley 7 is trained.

The first cross section 3rd is above the second cross-sectional area 4th arranged, creating the recess 5 above the second cross section 4th is arranged. The bottom edge of the recess 5 extends essentially at the same height as the upper edge of the first cross-sectional partial area 3rd , whereby the load absorption and load transfer can take place advantageously. The rail 15 lies on the top of the second cross-sectional partial area 4th on.

The trolley 7 is - as in 1 visible - between the bars 1 , 2nd arranged. The one on the rails 15 over the impeller 6 guided trolley 7 is parallel to the longitudinal direction of the bar 1 , 2nd and so perpendicular to the image plane of the 1 and the 2nd movable. The trolley 7 so loads the beam 1 with static and dynamic forces, which forces from the weight of the trolley 7 that on the trolley 7 acting load, the movement of the trolley 7 if necessary, take up the load.

It is the first cross section 3rd and the second cross section 4th for transferring forces to the beam 1 connected.

It is the first cross section 3rd and the second cross section 4th made from a solid wooden cross section with wooden slats, which wooden slats in 2nd are shown in detail A. The cross-sectional areas 3rd , 4th are formed by glued together wooden slats, which wooden slats extend essentially horizontally. The longitudinal direction of the slats and the beam 1 are the same and so perpendicular to the image plane of the 1 . The expert is familiar with such cross-sections from glued wooden lamellas also as glue binders. The invention is also characterized in that for producing the cross-sectional partial areas 3rd , 4th a commercially available glue binder can be used, which glue binder for the beams 1 , 2nd be put together.

As a rule, the wooden slats can extend horizontally, as is usual with glue-laminated girders. However, a person skilled in the art can also provide that taking into account the special load on the beams 1 , 2nd in the use discussed here in a girder crane, the adhesive joints are arranged in an orientation deviating from the horizontal extent. The person skilled in the art can arrange the adhesive joints in such a way that they are oriented at a right angle to a main cutting force in order to avoid shear stress on the wooden workpiece surrounding the adhesive joint.

It can be the first cross section 3rd and / or the second cross-sectional partial area 4th be provided with a fire protection agent, whereby in 1 and 2nd the fire protection agent is not entered due to the optional arrangement on at least the free surfaces of the cross-sectional partial areas. The person skilled in the art can apply the fire protection agent to those surfaces of the cross-sectional partial areas 3rd , 4th arrange which cross-sectional partial areas 3rd , 4th have a small or in particular too small volume, so that the load-bearing capacity takes into account the volume of the cross-sectional areas that burns in the event of a fire 3rd , 4th is guaranteed.

The first cross section 3rd has, for example, a small first width 17th on. The person skilled in the art can, for example, on the free surfaces of the first cross-sectional partial area 3rd order a fire protection agent. The fire protection agent can be, for example, a hardwood panel, which hardwood panel is the free surface of the cross-sectional partial area 3rd , 4th from a softer wooden workpiece.

Alternatively or in addition to the arrangement of fire protection agents on the free surfaces of the cross-sectional partial areas 3rd , 4th can the bar 1 dimensioned so that in the event of a fire, the first cross-sectional area 3rd is regarded as a static element that is not significantly resilient. This assumption can be based on the fact that the first cross-sectional area 3rd a small first width 17th or low height 19th so that in the event of a fire, the load-bearing capacity of the first cross-sectional area 3rd because of the burned volume of the wood material no longer exists or only to a negligible extent. The person skilled in the art can understand the second cross-sectional partial area 4th with a second width 18th and a second height 20th Dimension such that only the second cross-sectional partial area 4th has the necessary load-bearing capacity to absorb and derive the dead loads and loads.

In the 2nd shown embodiment of the girder crane according to the invention comprises a screw 12th what screw 12th through the first cross-sectional partial area 3rd and in the second cross-sectional partial area 4th extends, the person skilled in the art also other connection methods and other shapes of the screw 12th for producing a composite of the first cross-sectional partial area 3rd and the second cross-sectional partial area 4th can provide. By means of this screw 12th can the first cross-sectional partial area 3rd at least during the production of the composite between the cross-sectional partial areas 3rd , 4th by, for example, additional gluing of the contact surfaces of the cross-sectional partial areas 3rd , 4th be biased.

The screw 12th can in the bar 1 be glued in.

The screw 12th is embedded in the cross-section of the wooden workpiece. When the bar heats up 1 protect the screw 12th surrounding cross-sectional areas 3rd , 4th the screw with its advantageous thermal properties 12th before warming. A reduction in the mechanical properties caused by heating can thus be prevented.

The first cross section 3rd and the second cross section 4th have a first vertical axis of inertia 9 or a second vertical axis of inertia 10th on what axes of inertia 9 , 10th are spaced from each other.

The person skilled in the art can choose the first width 17th and the second width is the spacing of the vertical axes of inertia 9 , 10th define. The in 1 bars shown 1 includes a flat outside surface of the beam 8th , resulting in a spacing of the vertical axes of inertia at the different widths 9 , 10th leads. The flat outside surface of the beam 8th certainly represents a special case; those skilled in the art can vary the widths and create an uneven beam outside surface 8th and maintaining the recess 5 a change in the spacing of the vertical axes of inertia 9 , 10th to reach.

The bars 1 , 2nd can by a cross connection 11 be connected, which cross-connection 11 at the first cross section 3rd connected. In the 1 The embodiment shown is characterized by the special case that the cross composite 11 at the top of the first cross-sectional partial area 3rd connected. This is not absolutely necessary, but it allows a space-saving arrangement of the elements of the girder crane. The cross-connection 11 can also at other points of the first cross-sectional partial area 3rd be connected with suitable connecting means.

The bars 1 , 2nd can on a head carrier 13 be stored. As with prior art girder cranes, the head girder extends at a right angle to the longitudinal direction of the girder 1 . Head carriers are usually in their longitudinal direction and thus transverse to the longitudinal direction of the beam 1 movably mounted so that the beam 1 by moving the head carrier 13 is movable transversely to its longitudinal direction. The bar 1 and possibly the bar 2nd can by means of a stiffening element 14 on the head carrier 13 be connected.

The stiffening element 14 can essentially be about the second height 20th of the second cross section 4th extend and so a transfer of the to the beam 1 ensure acting acceleration forces. This in 2nd stiffening element shown 14 is only slightly above the second height 20th deviating height at the second cross-sectional partial area 4th connected. The exit element is advantageous 14 on that side of the bar 1 arranged on which side of the bar 1 mainly pressure forces from the beam 1 on the stiffening element 14 be transmitted.

The stiffening element 14 points to the trolley 7 towards a sloping edge 16 to make room for the trolley moving at right angles to the image plane 7 to accomplish.

The bar 1 is by one from the trolley 7 originating force F1 charged. That power F1 is due to the trolley’s own load 7 and, if necessary, by the on the trolley 7 acting load justified when lifting objects. Below are the advantageous properties of the girder crane according to the invention with regard to the absorption and transfer of forces such as the force F1 discussed. This following discussion is characterized, among other things, by the fact that the inherent loads of the elements can be neglected, as is customary when calculating girder cranes according to the prior art.

Because of the eccentricity of the through the rail 15 predetermined force introduction point of the force F1 to the second vertical axis of inertia 10th creates the power F1 in the transition area between the first cross-sectional partial area 3rd and the second cross-sectional partial area 4th a cutting moment. The second cross section 4th is sufficiently large that this cutting moment M1 recorded and in a support of the second cross-sectional partial area 4th such as the head carrier 13 at the in 1 and 2nd shown embodiment can be removed.

That in the first cross section 3rd effective cutting moment M1 can advantageously over the cross composite 11 be removed. With an advantageous articulation of the cross-connection 11 becomes the cross-link 11 only loaded by cutting tensile forces or cutting pressure forces, as also in 2nd is illustrated by an arrow.

The 2nd shows a screw in cross section 12th . There can be several screws 12th along the length of the bar 1 be distributed. In the 2nd shown screw 12th can the moment of force M1 between the cross-sectional sections 3rd , 4th transfer. To avoid tensile forces on the contact surface between the cross-sectional partial areas 3rd , 4th Which tensile forces can cause the contact surfaces to diverge can be several over the first width 17th distributed screws can be arranged.

3rd shows the in 1 and 2nd Shown embodiment of the beam crane according to the invention in a view from above. Based on 3rd is a possible formation of the cross-link 11 what cross composite 11 the bars 1 , 2nd connected, easily recognizable. The cross bonds 11 form a framework comprising vertical elements, which vertical elements essentially at an angle of 90 ° to the longitudinal axes of the beams 1 , 2nd is arranged, and diagonally arranged elements, so as to be static and dynamic resilient connection between the beams 1 , 2nd to reach.

The cross bonds 11 can - such as in 2nd shown - at the top of each bar 1 , 2nd be connected. The specialist here creates a statically and dynamically resilient connection by means of screws, nails or even adhesive joints.

It is also conceivable that the cross bonds 11 in one in the first cross-sectional partial area 3rd trained receiving recess is introduced and there with the first bar 1 connected is. The expert can also cross-connect 11 an anchor-like shape and that in the first cross-sectional area 3rd trained receiving recess give a suitable shape, so that a typical carpenter connection between the cross bond 11 and the bar 1 can be manufactured.

4th shows a view from the side of the in the 1 to 3rd illustrated embodiment.

5 shows a schematic representation of a further possible embodiment of the beam crane according to the invention. The in 5 and 7 beam crane shown includes a beam 1 Beam (industrial term: single girder overhead traveling crane), which is the only beam 1 a first cross section 3rd and a second cross section 4th includes which cross-sectional partial areas 3rd , 4th are connected to each other for the transmission of forces. The cross-sectional areas 3rd , 4th have a first width 17th and a first height 19th or a second width 18th and a second height 20th on.

It is the first width 17th less than the second width 18th so that two recesses 5 in the bar 1 be formed. In these recesses 5 is a rail (In 5 not shown) for receiving an impeller 6 which is below the bar 1 extending trolley 7 arranged.

The first cross section 3rd and the second cross section 4th are made of a wooden material, which achieves the advantageous effects mentioned above. The cross-sectional areas 3rd , 4th can be designed as solid wooden cross sections or in a box shape. In principle, other shapes such as a U-profile, C-profile or I-profile would also be conceivable.

The non-positive connection of the cross-sectional sections 3rd , 4th can by a screw 12th be made what screw 12th itself in the first cross-sectional partial area 3rd and in the second cross-sectional partial area 4th can extend. The person skilled in the art can also use several screws 12th provide.

The second cross section 4th is centered under the first cross section 3rd arranged. The first vertical axis of inertia 9 and the second vertical axis of inertia 10th are congruent.

6 shows a further embodiment of the beam support according to the invention comprising a beam 1 . The bar 1 comprises a first cross-sectional partial area 3rd and a second cross section 4th , being a first width 17th of the first cross section 3rd is less than the adjacent second width 18th of the second cross section 4th . This creates a recess 5 for arranging notes (in 6 not shown) created. On this track is one or more wheels 6 a trolley 7 stored.

7 shows a further embodiment of the girder crane according to the invention comprising
a bar 1 , wherein at least one beam extending in a longitudinal direction of the beam 1 a beam cross section with at least one rail 15 having. The rail 15 is by means of a screw 12th on the underside of the beam 1 attached so that the wheels 6 one under the bar 1 arranged trolley 7 to the side of the beam 1 find a tread.

In the 7 The schematically illustrated embodiment of the beam crane according to the invention is characterized in that the beam 1 is made of a wooden material. The bar 1 comprises a cross-sectional partial area with a width and a height.

QUOTES INCLUDE IN THE DESCRIPTION

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Patent literature cited

• EP 2942317 [0002]
• EP 0051270 A2 [0003]

Claims (15)

Beam crane comprising - at least one beam (1, 2), which beam (1, 2) extends in a longitudinal direction of the beam and which beam (1, 2) has a beam cross section designed as a full cross section, - at least one arranged on the beam (1, 2) Rail (15), on which rail (15) a trolley (7) is mounted, characterized in that the beam (1, 2) is made from a wood-based material. Girder crane after Claim 1 characterized in that the beam cross-section has a first cross-sectional partial area (3) having a first width (17) and a first height (19) and a second cross-sectional partial area (4) having a second width (18) and a second height (20), which first cross-sectional beam section (3) and which second cross-sectional section (4) are connected to one another for the transmission of forces, the first width (17) being less than the second width (18), so that the cross section of the beam has a recess (5) parallel to it the rail (15) extends longitudinally in the direction of extent of the beam. Girder crane after Claim 2 , characterized in that a first vertical axis of inertia (9) of the first cross-sectional area (3) and a second vertical axis of inertia (10) of the second cross-sectional area (4) are spaced apart. Girder crane according to one of the Claims 2 to 3rd , characterized in that the first cross-sectional partial area (3) is arranged above the second cross-sectional partial area (4). Girder crane according to one of the Claims 1 to 4th , characterized in that the trolley (7) is arranged in an area between the two bars (1, 2). Girder crane according to one of the Claims 1 to 5 , characterized in that the two beams (1, 2) are connected by a cross connection (11), which cross connection (11) is connected to the first cross-sectional partial area (3). Girder crane after Claim 6 , characterized in that the transverse composite (11) is arranged at an angle of 90 ° or at an angle deviating from 90 ° to the longitudinal direction of the beams (1, 2). Girder crane according to one of the Claims 6 or 7 , characterized in that the cross assembly (11) is connected to the top of the first beam cross-section. Girder crane according to one of the Claims 1 to 8th , characterized in that the beam cross-section is made of glued wooden slats, two wooden slats each having an adhesive joint, an adhesive joint being arranged in the contact area between the first cross-sectional partial area and the second cross-sectional partial area. Girder crane after Claim 9 , characterized in that an adhesive joint is arranged at an angle of 90 ° to a main beam cutting force. Girder crane according to one of the Claims 1 to 10th , characterized in that the first cross-sectional partial area (3) is prestressed against the second cross-sectional partial area (4) at least during the manufacture of the beam comprising the first cross-sectional partial area (3) and the second cross-sectional partial area (4). Girder crane according to one of the Claims 1 to 11 Which beam crane is loaded by its own load and can be loaded by a load, characterized in that the second cross-sectional partial area (4) is dimensioned for the transfer of the own load. Girder crane according to one of the Claims 1 to 12th , characterized in that the first cross-sectional partial area (3) and / or the second cross-sectional partial area (4) is provided with a fire protection agent. Girder crane according to one of the Claims 1 to 13 , characterized in that the beams (1, 2) are mounted on head supports (13). Girder crane according to one of the Claims 1 to 14 , characterized in that the beam is connected to the head support (13) via a stiffening element (14), which stiffening element (14) is connected to the second cross-sectional partial area (4) via the second height (20).

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