EP4015433A1 - Load suspension device and lifting device - Google Patents

Abstract

The invention relates to a load handling device (1) for a hoist with at least one load handling device (2), in particular a traverse, with at least one load handling device coupling structure (7, 8) and with at least one connecting element (9 to 15), which has at least one lifting device ( 16.1 to 16.3, 17.1 to 17.4) and/or at least one attachment structure (18) for a sling (16.1 to 16.3, 17.1 to 17.4) and at least one first connecting element coupling structure (19) that is complementary to the load handling device coupling structure (7, 8) includes. The connecting element (9 to 15) is or can be fastened to the load handling device (2) in a detachable, non-destructive manner and the first connecting element coupling structure (19) is in mechanical engagement with the load handling device when the connecting element (9 to 15) is in the fastened state on the load handling device (2). -Coupling structure (7, 8). The at least one connecting element (9 to 15) comprises a second connecting element coupling structure (22) congruent with the load handling device coupling structure (7, 8), wherein the connecting element (9 to 15) is at least essentially plate-shaped and the first connecting element coupling structure (19) and the second connecting element coupling structure (22) are arranged or formed on opposite flat sides of the connecting element (9 to 15).

Description

The invention relates to a load handling device for a hoist.

The invention further relates to a hoist comprising such a load handling device.

Load lifting devices are generally known from the prior art, which include load lifting devices, attachment devices and carrying devices.

Load handling devices are generally understood to mean devices that do not belong to the hoist and that can be connected to a carrying element of the hoist in order to pick up and release a load. Such a load handling device is, for example, a traverse, which is understood to mean a mechanical support that is used for stabilization, attachment or connection. As a load handling device, the traverse is used when attaching loads and for load distribution, for example to attach a tether to a crane hook using a crossbeam.

Supporting means are generally understood to mean devices that are permanently connected to the hoist for taking up load handling equipment, slings or loads.

Slings are generally understood to mean devices that do not belong to the hoist and that create a connection between the suspension means and the load or the suspension means and load handling equipment.

For example, from the DE 10 2016 222 211 A1 a lifting arrangement for lifting a load is known. The lifting assembly comprises an upper part and a number of independent lower parts, the upper part comprising a lifting beam, a suspension assembly for suspending the lifting beam from a crane hook, and a latching assembly comprising an actuator assembly. The latch assembly is intended to engage the top with a bottom. A base includes a lifting tool intended to be connected to a load and a latching interface intended to be engaged with the latch assembly of the top. The latch assembly is attached to the lifting beam and includes side plates intended to contain the actuator assembly, the side plates including through holes intended to receive linear actuators of the actuator assembly.

Furthermore, from the DE 10 2014 017 550 A1 an adapter for a hoist for handling load handling devices with a hoist-side first coupling element is known. The coupling element can be arranged on a traction device or on a suspension device. Furthermore, a second coupling element on the load-carrying means side is provided, which can be arranged on the load-carrying means, it being possible for the first and the second coupling element to enter into a releasable non-positive and positive connection with one another.

Also describes the DE 93 06 542 U1 a load traverse with two profile rails of the same design, arranged in mirror image and connected to one another, as well as elements for attaching the traverse to a hoist and for attaching a load to the traverse. The cross-sectional profile of the profile rails consists of two hook-shaped sections arranged in mirror image to the longitudinal center line and the two profile rails form a hollow box, the top and bottom of which are formed by two of the end regions of the hook-shaped sections of the cross-sectional profile pointing towards one another.

The invention is based on the object of specifying a load handling device for a hoist that is improved compared to the prior art and an improved hoist.

The object is achieved according to the invention by a load handling device which has the features specified in claim 1, and by a hoist which has the features specified in claim 9.

Advantageous configurations of the invention are the subject matter of the dependent claims.

The load handling device according to the invention for a hoist comprises at least one load handling device, in particular a traverse, with at least one load handling device coupling structure and at least one connecting element. The connecting element comprises at least one stop means and/or at least one fastening structure for a stop means and at least one second connecting element coupling structure which is complementary to the load handling device coupling structure. The connecting element is or can be fastened to the load-carrying device in a detachable, non-destructive manner and the second connecting element-coupling structure is in mechanical engagement with the load-carrying device-coupling structure when the connecting element is in the fastened state on the load-carrying device.

By means of the load handling device according to the invention, a large number of functions can be implemented due to the possible optional coupling of a load handling device with different connecting elements each comprising at least one sling and/or at least one fastening structure for a sling. For example, various connecting elements can be selected from a modular system. Thus, by attaching different connecting elements to the load handling device, a large number of variants can be implemented and safely mastered, and a load handling device can be used for different applications different fasteners are used. This results in significant cost savings and resource savings, in addition to a reduction in the storage space required for the load handling device, in particular compared to load handling devices on which the slings are firmly welded to the load handling device. The complementary design of the load handling device coupling structure and the second connecting element coupling structure enables a mechanical key-lock principle to be implemented. In this case, the load handling device coupling structure and the first connecting element coupling structure are designed and shaped in particular in such a way that the connecting element can be mounted on the load receiving device in a fixed, predetermined number of positions relative to one another, so that assembly errors and the resulting operational hazards can be avoided.

Furthermore, the at least one connecting element has at least one second connecting element coupling structure that is congruent with the load handling device coupling structure. This makes it possible for a further connection element to be able to be fastened to a connection element with its first connection element coupling structure.

In addition, the connecting element is at least essentially plate-shaped and the first connecting element coupling structure and the second connecting element coupling structure are arranged or formed on opposite flat sides of the connecting element. Such a design of the connecting element enables simple manufacture and use of the same.

In a possible further configuration of the load handling device, the mechanical engagement between the first connecting element coupling structure and the load handling means coupling structure is form-fitting and/or force-fitting. Thus, a secure and stable mechanical connection between the Load handling devices and the connecting element can be realized with simple disassembly at the same time.

In a further possible configuration of the load handling device, the load handling device coupling structure and thus also the congruent second connecting element coupling structure each have a material projection. Furthermore, the first connecting element coupling structure has a material recess that is complementary to the material projection. Such a design of load handling device coupling structure and first connecting element coupling structure as well as second connecting element coupling structure is easy to implement on the one hand and easy to handle during assembly of the connecting element on the load handling device on the other hand. Furthermore, a particularly stable and reliable positive and/or non-positive connection can be produced.

In a further possible configuration of the load handling device, the material projection and the material recess have a round or an oval or a triangular or a quadrangular cross section and thus enable simple and intuitive positioning of the connecting element on the load handling device.

In a further possible configuration of the load handling device, a respective diameter of the material projection and the material recess increases continuously or non-linearly, in particular exponentially, starting from a head of the material projection to a foot of the same and starting from a bottom of the material recess to an opening of the same. On the one hand, this simplifies the insertion of the material projection into the material recess when the connecting element is installed on the load handling device. Furthermore, the occurrence of mechanical stress peaks and/or their size can be reduced, in particular in the case of the exponential increase, in the assembled state of the material projection in the material recess.

In a further possible embodiment of the load handling device, the material projection and the material recess are formed in a common molded part, the molded part being non-positively, materially and/or positively fastened in a complementary opening of a connecting element body. In this way, compared to a possible solid and one-piece design of the connecting element, in which this is produced from a solid body, for example by means of machining processes, a significant saving in material and simplified production can be realized.

In a further possible embodiment of the load handling device, depending on the material of the connecting element, it is also possible to design it as a homogeneous and one-piece molded part, in particular without joints, with the molded part being designed, for example, as a deep-drawn part, extruded part, cast part, pressed part, injection-molded part or sintered part .

In a further possible configuration of the load handling device, the load handling device comprises a plurality of load handling device bores arranged in a defined pattern and at a defined distance from the load handling device coupling structure, and the connecting element comprises a number of connecting element bores formed in a congruent pattern. In this case, a screw or a bolt is guided or can be guided through corresponding load-carrying means bores and connecting element bores, by means of which the connecting element is screwed or can be screwed to the load-carrying means. The load handling device bore can also be designed as a threaded bore, for example. The bores enable the connecting element to be fastened to the load-receiving means in a simple and reliable manner so that it can be detached in a non-destructive manner. For example, the patterns and distances are designed differently depending on the application and/or permissible carrying capacity of the load-carrying device, so that incorrect assembly of connecting elements with, for example, a lower carrying capacity on load-carrying devices with, for example, a higher carrying capacity can be reliably avoided.

In a further possible configuration of the load handling device, a plurality of connecting elements are arranged one behind the other, in particular in a series circuit, with the first connecting element coupling structure of a connecting element being in mechanical engagement with the second connecting element coupling structure of the directly adjacent connecting element between two directly adjacent connecting elements. The series connection of, in particular, differently designed connecting elements, for example connecting elements with different attachment means and/or different fastening structures for attachment means, enables multifunctional use of the load handling device. The connecting elements and the attachment means and/or fastening structures for attachment means arranged on them can be used for coupling to at least one support means of a hoist and for coupling to at least one load.

The connection between the connecting elements is designed in particular analogously to the previously described connection between the connecting element and the load handling device and has corresponding advantages. In one possible embodiment, the connecting elements connected in series are fastened jointly to the load-carrying means by means of screws or bolts passed through all of the connecting element bores.

The hoist according to the invention comprises at least one aforementioned load handling device. The hoist is characterized by a large number of functions due to the design of the load handling device, in which a selective coupling of a load handling device with different connecting elements, each comprising at least one sling and/or at least one fastening structure for a sling, is possible. For example, various connecting elements can be selected from a modular system. Thus, by attaching different connecting elements to the lifting device, a large variety of variants can be realized and can be mastered safely and a load handling device with different connecting elements can be used for different applications.

Figur 1

schematisch eine perspektivische Explosionsdarstellung einer Lastaufnahmeeinrichtung für ein Hebezeug,

Figur 2

schematisch eine perspektivische Ansicht eines vergrößerten Ausschnitts der Lastaufnahmeeinrichtung gemäß Figur 1,

Figur 3

schematisch eine perspektivische Ansicht eines vergrößerten weiteren Ausschnitts der Lastaufnahmeeinrichtung gemäß Figur 1,

Figur 4

schematisch eine perspektivische Darstellung eines Verbindungselements mit einem Anschlagmittel,

Figur 5

schematisch eine perspektivische Darstellung eines weiteren Verbindungselements mit einem Anschlagmittel,

Figur 6

schematisch eine perspektivische Darstellung eines weiteren Verbindungselements mit einem Anschlagmittel,

Figur 7

schematisch eine perspektivische Darstellung eines weiteren Verbindungselements mit mehreren Anschlagmitteln,

Figur 8

schematisch eine perspektivische Darstellung eines weiteren Verbindungselements mit einer Befestigungsstruktur für ein Anschlagmittel,

Figur 9

schematisch eine perspektivische Ansicht eines Formteils mit einer ersten Verbindungselement-Koppelstruktur und einer zweite Verbindungselement-Koppelstruktur und

Figur 10

schematisch eine Seitenansicht des Formteils gemäß Figur 9.

Exemplary embodiments of the invention are explained in more detail below with reference to drawings. Show in it:

figure 1

schematically a perspective exploded view of a load handling device for a hoist,

figure 2

schematically shows a perspective view of an enlarged section of the load handling device according to FIG figure 1 ,

figure 3

schematically shows a perspective view of an enlarged further section of the load handling device according to FIG figure 1 ,

figure 4

schematically a perspective view of a connecting element with a stop means,

figure 5

schematically a perspective representation of a further connecting element with a stop means,

figure 6

schematically a perspective representation of a further connecting element with a stop means,

figure 7

schematically a perspective representation of a further connecting element with several stop means,

figure 8

a schematic perspective view of a further connecting element with a fastening structure for a sling,

figure 9

schematically a perspective view of a molded part with a first connecting element coupling structure and a second connecting element coupling structure and

figure 10

schematically shows a side view of the molded part according to FIG figure 9 .

Corresponding parts are provided with the same reference symbols in all figures.

In figure 1 a possible embodiment of a load handling device 1 according to the invention for a hoist, for example for a crane, is shown. the figures 2 and 3 show perspective views of different sections of the load handling device 1 for clarification.

The load-carrying device 1 comprises a load-carrying means 2, which is designed as a so-called traverse.

In the exemplary embodiment shown, the load-carrying means 2 comprises a plurality of attachment means 3.1 to 3.8, which are provided for coupling the load-carrying means 2 to a carrying means 4, for example a hook of a crane. These attachment means 3.1 to 3.8 have an essentially unchangeable position on the load handling device 2. A number of these fixed stop means 3.1 to 3.8 can vary in any way. In one possible embodiment, the load-carrying means 2 does not include such fixed attachment means 3.1 to 3.8.

Furthermore, the load-carrying means 2 comprises a plurality of further attachment means 5.1 to 5.3, which are designed to couple the load-carrying means 2 to other attachment means (not shown) and/or a load to be moved. These slings 5.1 to 5.3 are each detachable on a firmly coupled to the load-carrying means 2, for example welded,

Fastening structure 6.1 to 6.3 attached. A number of these stop means 5.1 to 5.3 and the fixed attachment structures 6.1 to 6.3 can vary in any way. In one possible embodiment, the load-carrying means 2 does not include such attachment means 5.1 to 5.3 and attachment structures 6.1 to 6.3.

In addition, the load-carrying means 2 comprises a further fixed fastening structure 6.4 designed as a toothing, a further fastening structure 6.5 that can be variably positioned on this fastening structure 6.4 and a further slinging device 5.5 arranged on this fastening structure 6.5, which is used to couple the load-carrying means 2 to further slinging means and/or not shown. or a load to be moved. Furthermore, the load-carrying means 2 comprises a further attachment structure 6.6 and another attachment means 5.5 arranged on this attachment structure 6.6, which is designed to couple the load-carrying means 2 to other attachment means (not shown) and/or a load to be moved. A number of such stop means 5.4, 5.5 and such attachment structures 6.4 to 6.6 can vary in any way. In one possible embodiment, the load-carrying means 2 does not include such attachment means 5.4, 5.5 and attachment structures 6.4 to 6.6.

The configurations of the illustrated load handling device 1 described above make it clear that load handling devices 1 are characterized by very diverse constructions. Standards have only been implemented to a limited extent because customer requirements are very individual and the creativity of commissioned designers is limitless. A large number of required functions of such load handling devices 1 or such attachment means 3.1 to 3.8, 5.1 to 5.5 and fastening structures 6.1 to 6.6 and their possible combinations result in an unmanageable variety of variants. Here, for example, the geometries and masses of loads to be transported are very different. The slings 3.1 to 3.8 can also be attached in very different ways by the hoist, for example a crane, be picked up and attaching the load itself involves weighing up many options.

In order to make the aforementioned variety of variants manageable, it is provided that the load handling device 2 comprises at least one load handling device coupling structure 7, 8, in the exemplary embodiment shown a coupling structure 7, 8 on each end face, to which a plurality of connecting elements 9 to 15 can be mechanically coupled .

The load-carrying means coupling structures 7, 8 are each non-positively, materially and/or positively attached to the load-carrying means 2, for example welded.

The load handling device coupling structures 7, 8 are at least essentially plate-shaped and each have a material projection V. This material projection V has a round cross section, with a diameter of the material projection V increasing non-linearly, in particular exponentially, starting from a head of the material projection V to a foot of the same. Furthermore, several load-carrying device bores B1 arranged in a defined pattern and at a defined distance from the material projection V are made in the plate-shaped load-carrying device coupling structures 7, 8 figure 1 are not provided with reference numbers. In the exemplary embodiment shown, the pattern is selected in such a way that the load suspension device bores B1 form the corners of an imaginary rectangle. The load handling device bores B1 can be designed as threaded bores.

Furthermore, the load handling device 1 comprises at least one connecting element 9 to 15, seven connecting elements 9 to 15 in the exemplary embodiment shown.

The connecting elements 9 to 15 each have at least one stop means 16.1 to 16.3, 17.1 to 17.4 and/or at least one fastening structure 18 for a sling 16.1 to 16.3, 17.1 to 17.4. The slinging means 16.1 to 16.3 are provided for coupling the load-carrying means 2 to a carrying means 4, for example a hook of a crane, and/or other slinging means, not shown. The stop means 17.1 to 17.4 are designed to couple the load handling means 2 to other stop means (not shown) and/or a load to be moved.

Each of the connecting elements 9 to 15 has a first connecting element coupling structure 19 which is complementary to the load handling device coupling structure 7, 8 and which is shown in FIGS Figures 4 to 8 is shown in more detail.

The first connecting element coupling structure 19 has a material recess A which is complementary to the material projection V and which is also in the Figures 4 to 8 is shown in more detail and also has a round cross section, a diameter of the material recess A starting from a bottom of the material recess A to an opening of the same non-linear, in particular increases exponentially.

The connecting elements 9 to 15 are also at least essentially plate-shaped, with the first connecting element coupling structures 19 each being arranged on a flat side of the respective connecting element 9 to 15 .

The connecting elements 9 to 15 comprise a plurality of connecting element bores B2 formed in a congruent pattern for the load handling device bores B1, which are shown in FIGS figures 1 and 2 are not provided with reference numbers. These are in figure 3 example of the connecting element 14 and in the Figures 4 to 8 shown for the connecting elements 11 to 15.

A screw 20 is guided through the mutually corresponding load suspension device bores B1 and connecting element bores B2, by means of which and exactly one connecting element 9 to 15 is screwed to the respective load handling device 2 by means of a screw nut 21 . Thus, the respective connecting element 9 to 15 is non-destructively detachably attached to the load handling device 2 and the first connecting element coupling structure 19 is in the attached state of the connecting element 9 to 15 on the load handling device 2 in mechanical engagement with the load handling device coupling structure 7, 8. The load handling devices are -Coupling structure 7, 8 and the connecting element coupling structure 19 are designed in such a way that the mechanical engagement between the second connecting element coupling structure 19 and the load handling device coupling structure 7, 8 is positive and/or non-positive.

In order, as shown, to arrange a plurality of connecting elements 9 to 15 in a series connection one behind the other on the load handling device 2, the connecting elements 9 to 11 and 13 to 15 have a side opposite the first connecting element coupling structure 19 which is congruent with the load handling device coupling structure 7, 8 second connecting element coupling structure 22, so that between two immediately adjacent connecting elements 9 to 15 the first connecting element coupling structure 19 of a connecting element 9 to 15 is mechanically engaged with the second connecting element coupling structure 22 of the directly adjacent connecting element 9 to 11, 13 to 15 stands. To ensure clarity, the second connecting element coupling structures 22 in figure 1 not provided with reference numbers.

In one possible embodiment, the first connecting element coupling structure 19 and the second connecting element coupling structure 22, in particular the material projection V and the material recess A, are formed in a common molded part 23, which is in the Figures 9 and 10 is shown in more detail.

The molded part 23 is in a complementary to this opening in the Figures 4 to 8 Connection element body 24 shown in more detail fuel, fuel and/or fastened in a form-fitting manner, for example pressed and/or welded and/or screwed into a thread.

figure 4 shows the connecting element 11 with a stop means 17.4 designed as a hook in a perspective view.

In figure 5 the connecting element 12 is shown in a perspective view with a stop means 16.2 designed as an eyelet.

figure 6 shows the connecting element 13 with a stop means 16.3 designed as a ring in a perspective view.

In figure 7 the connecting element 12 is shown in a perspective view with two stop means 17.2, 17.3 each designed as a hook.

figure 8 shows the connecting element 13 with a fastening structure 18 comprising a plurality of bores in a perspective view.

In the Figures 9 and 10 the molded part 23 with the material recess A and the material projection V is shown.

The material projection V and the complementary material recess A each have a round cross section, with a diameter of the material recess A increasing non-linearly, in particular exponentially, starting from a bottom of the material recess A to an opening thereof, and a diameter of the material projection V starting from its base increases non-linearly, in particular exponentially, towards its head.

In one possible embodiment, the molded part 23 shown is connected to a corresponding body, not shown in detail, analogously to the connecting element body 24 in order to produce the load handling device coupling structure 7 , 8 .

REFERENCE LIST

1

load handling device

2

load handling equipment

3.1 to 3.8

slings

4

carrying means

5.1 to 5.5

slings

6.1 to 6.6

mounting structure

7

coupling structure

8th

coupling structure

9 to 15

fastener

16.1 to 16.3

slings

17.1 to 17.4

slings

18

mounting structure

19

first connector coupling structure

20

screw

21

nut

22

second connector coupling structure

23

molding

24

fastener body

A

material recess

B1

Load handler bore

B2

fastener bore

V

material advantage

Claims (9)

Load handling device (1) for a hoist - With at least one load handling device (2), in particular a traverse, with at least one load handling device coupling structure (7, 8) and - With at least one connecting element (9 to 15), which - at least one stop means (16.1 to 16.3, 17.1 to 17.4) and/or at least one fastening structure (18) for a stop means (16.1 to 16.3, 17.1 to 17.4), - comprises at least one first connecting element coupling structure (19) which is complementary to the load handling device coupling structure (7, 8), - wherein the connecting element (9 to 15) is or can be detachably attached to the load handling device (2) in a non-destructive manner and the first connecting element coupling structure (19) in the attached state of the connecting element (9 to 15) on the load handling device (2) is in mechanical engagement with the load handling device coupling structure (7, 8), - wherein the at least one connecting element (9 to 15) comprises a second connecting element coupling structure (22) congruent with the load handling device coupling structure (7, 8), - wherein the connecting element (9 to 15) is at least substantially plate-shaped and - wherein the first connecting element coupling structure (19) and the second connecting element coupling structure (22) are arranged or formed on opposite flat sides of the connecting element (9 to 15). Load handling device (1) according to claim 1, wherein the mechanical engagement between the first connecting element coupling structure (19) and the load handling means coupling structure (7, 8) is positive and/or non-positive. Load handling device (1) according to any one of the preceding claims, wherein - the load handling device coupling structures (7, 8) each have a material projection (V) and - The first connecting element coupling structure (19) has a material recess (A) complementary to the material projection (V). Load handling device (1) according to claim 3, wherein the material projection (V) and the material recess (A) have a round or an oval or a triangular or a quadrangular cross-section. Load handling device (1) according to claim 4, wherein a respective dimension, in particular a respective diameter, of the material projection (V) and the material recess (A) starting from a head of the material projection (V) to a foot of the same and starting from a bottom of the material recess ( A) increases continuously or non-linearly, in particular exponentially, at least in sections towards an opening of the same. Load handling device (1) according to any one of claims 3 to 6, wherein - The material projection (V) and the material recess (A) are formed in a common molded part (23) and - The molded part (23) is fastened in a complementary opening of a connecting element body (24) in a non-positive, material and/or form-fitting manner. Load handling device (1) according to any one of the preceding claims, wherein - the load handling device (2) comprises a plurality of load handling device bores (B1) arranged in a defined pattern and at a defined distance from the load handling device coupling structure (7, 8), - the connecting element (9 to 15) comprises a plurality of connecting element bores (B2) formed in a congruent pattern and - a screw (20) or a bolt, by means of which the connecting element (9 to 15) is screwed or can be screwed to the load handling device (2), is or can be guided through corresponding load handling device holes (B1) and connecting element holes (B2). is. Load handling device (1) according to any one of the preceding claims, wherein - Several connecting elements (9 to 15) are arranged one behind the other and - between two directly adjacent connecting elements (9 to 15), the first connecting element coupling structure (19) of a connecting element (9 to 15) is in mechanical engagement with the second connecting element coupling structure (22) of the immediately adjacent connecting element (9 to 15). Hoist comprising at least one load handling device (1) according to one of the preceding claims.

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