EP2135834A1 - Crane, preferably mobile or caterpillar crane - Google Patents

Abstract

The crane has an extension arm with a controller, and global positioning system (GPS)-receivers (26) receiving satellite-based systems for determining a global position of different crane components such as main extension arm (14), pointed extension arm (16), erecting crane extension arm (20), anchoring trestles (18A, 18B), erecting crane ballast (22) and/or hook block. A reference-GPS receiver (28) is arranged near a rotary axis (12) of an upper carriage (10) of the crane. Values derived from the receivers are wirelessly transmitted to the controller.

Description

The invention relates to a crane, preferably a mobile or crawler crane, with a series of mobile crane components, such as a main boom, guy blocks, a hook block and other moving elements.

For crane operation it is basically important to know the exact position of the moving parts and elements. Mobile crane components may be, for example, the following elements: the main boom, the luffing jib, the derrick boom, the jib and guying rods, the derrick ballast and the hook hook on which the load is received. Of course, this list is only an example. The determination of the position of the movable components is primarily used to determine the unloading of the load. Load unloading is a significant amount of overload protection. In conventional cranes, the respective positions of the moving components are calculated from existing geometric data, such as the component length, and from geometry values obtained via sensors. In the case of a mobile crane, for example, the ejection state of the telescopic shots of the main boom and the rocking angle of the main boom can serve. In a row From crane configurations, the outreach can be calculated from this. The respective data are passed on from the existing sensors to a crane control and processed there. For example, this calculates the load that can be picked up at a given radius.

From the EP 0 921 093 B1 It is in this context known to realize a system for measuring the tilt angle of a crane via a non-contact rangefinder, which is attached to the nose section of a first boom and measures the distance to a second boom, which is pivotally connected to the first boom. The non-contact distance measuring device detects the distance between the two arms and passes it on to a control device which converts the measured distance into the tilt angle.

The aforementioned methods all have in common that they use the existing geometric data of the components as a basis for calculating the position. In real operation, the existing geometry data of the components deviate from the theoretical geometry data. These are - especially for large cranes - not just negligible inaccuracies that are not to be considered. The components are subject to severe and insufficiently detectable deformations in crane operation, which can lead to sometimes considerable deviations of the ideal geometry data. These deformations thus justify the uncertainties of the measurement and calculation results. To compensate for such deformation uncertainties, it has already been proposed to use several inclinometers on a boom, as exemplified in FIG. 2 is shown. The FIG. 2 represents with the dashed lines how the various components can be deformed in reality.

The object of the present invention is now to provide a crane that allows the exact position determination of the various components or elements of the crane in operation, the real deformations of the components are fully taken into account.

According to the invention this object is achieved by the combination of the features of claim 1.

Accordingly, a crane is provided with a boom with a control and with means for determining the position of the different crane components, in which these means for determining the position consist of receivers of a satellite-based system for global positioning. Each of these receivers receives its exact position via the satellite-supported system, which can be passed on to the crane control and used there for exact position determination. Thus, the control of the end positions of the mobile crane component can be specified exactly. These position details are now completely independent of possible deflections or other deformations of the mobile crane components or elements.

Advantageous embodiments of the invention will become apparent from the subsequent claims to the main claim.

According to a first advantageous embodiment of the invention, the receivers of the satellite-based system for worldwide position determination are receivers for the GPS system which is used worldwide. These GPS receivers can be used to precisely determine the position of the respective mobile crane components. A controller can calculate distances from the respective signals of the GPS receiver. If absolute and unaltered signals are supplied, they can be processed directly by the controller.

It is particularly advantageous if a reference receiver is arranged on the crane, to which the values of the remaining receivers can be related. As a result, inaccuracies and distortions that actually occur can be compensated for by reference to the reference receiver. If all GPS receivers now supply their data to the controller, the difference in position between the reference receiver and the respective receivers on the moving components or elements can be used to determine the position inaccuracies actually applied be filtered out again. This means that even changing inaccuracies can be filtered out because the reception time of each receiver is known exactly.

For ease of calculation, the reference receiver is located near the axis of rotation of the crane, preferably near the axis of rotation of the mobile crane's uppercarriage.

It is particularly advantageous that the values originating from the receivers can be transmitted wirelessly to the controller. But it is also possible to connect all receivers via cable, in particular a bus system.

• das Teleskopieren eines Auslegers,
• das Wippen eines Auslegers und/oder
• das Verändern der Durchbiegung eines Auslegers, beispielsweise wegen der Aufnahme bzw. dem Absetzen einer Last.

Advantageously, all kinds of movements are detected by the GPS receivers. So it is irrelevant, because of which movement the discharge changes. Examples of such movements are

• telescoping a jib,
• the rocking of a boom and / or
• changing the deflection of a boom, for example, because of the inclusion or the discontinuation of a load.

By attaching a GPS receiver to the load, the position of the load itself can be determined.

Finally, the data transmitted via the receiver can also be used to determine the working area via the controller. The work area is here the freedom of movement in relation to the working area of other cranes or, for example, the inclusion of fixed interfering edges, for example of neighboring houses. The workspace is composed of the "envelope" of each of the receiver-provided locations and resulting links. Thus, turning and rocking movements are always detected and collisions are avoided. The working space of the crane is provided and monitored over the known widths of the components with appropriate safety impacts. At defined distances of the working area to interference edges, the controller can respond appropriately. This can be a warning or an intervention in the speed of movement of the component in question to the standstill of the entire crane range. Power lines, other cranes, houses, trees or areas that may not be used for any other reason can be referred to as interference edges.

The presented here system for determining the position of the components can be used in addition to a known in the crane control crane monitoring system conventional type to create a diverse monitoring system. In addition to the values calculated from the conventional system, the exact position could be determined here by the satellite-based system for determining the position of the globe worldwide.

1. 1. Die Länge des Hauptauslegers und des weiteren Auslegersystems und
2. 2. Prüfung auf vorhandenes Auslegersystem und teilweise vorhandene Komponenten. Diese ist möglich, da bei Fehlen einer Komponenten ja kein Positionssignal gesendet werden kann.

The positions that the GPS receivers deliver to the controller can also be used to check the setup state. Typically, the crane operator enters into the controller data relating to the existing boom system and other components on the crane, as well as data on the length of the main boom and the further boom system. Some information from the crane operator can be checked for the first time via the received signals. By way of example, mention should be made of:

1. 1. The length of the main boom and the other boom system and
2. 2. Check for existing boom system and partially existing components. This is possible because in the absence of a component yes no position signal can be sent.

Figur 1:

eine schematische Darstellung des Oberwagens eines Mobilkrans gemäß der vorliegenden Erfindung,

Figur 2:

eine schematische Darstellung des Oberwagens eines Mobilkrans, anhand der die möglichen Durchbiegungen langgestreckter Bauteile verdeutlicht sind und

Figur 3:

eine schematische Darstellung gemäß Figur 1 zur Verdeutlichung der Durchbiegung in Folge der Lastaufnahme.

Further features, details and advantages of the invention will become apparent from an embodiment shown in the drawing. Show it:

FIG. 1:

a schematic representation of the upper carriage of a mobile crane according to the present invention,

FIG. 2:

a schematic representation of the upper carriage of a mobile crane, based on the possible deflections of elongated components are illustrated and

FIG. 3:

a schematic representation according to FIG. 1 to illustrate the deflection as a result of load absorption.

In the FIG. 1 the superstructure 10 of a mobile crane not shown here is shown schematically. The superstructure 10 is rotatable about a rotation axis 12 in a known manner. At the superstructure is a main boom 14 and at this a luffing jib 16 hinged. In addition, two guy blocks 18A and 18B are provided. The mobile crane shown here also has a derrick boom 20 and a derrick ballast 22. On the boom hangs a load 24. Further details of the structure of the mobile crane are known in the art, so that can be dispensed with a further detailing of the structure at this point.

According to the present invention, the respective position of the mobile crane components or elements 14, 16, 18A, 18B and 22 can now be determined by corresponding receivers of a satellite-based system for global position determination 26. These receivers are the currently marketed system so-called GPS receiver.

The GPS receivers 26 provide the spatial position (X, Y, Z position) of any mobile crane component. For this purpose, the GPS receiver 26 are each arranged at the distal end of the respective components. On the mobile crane, a reference GPS receiver 28 is mounted in the vicinity of the axis of rotation 12 of the superstructure 10. So here is always a difference calculation between the reference GPS receiver 28 and the individual GPS receivers 26 at the end of each movable components are carried out for position determination. Also suddenly applied position inaccuracies can be averaged out again. Also, a position determination of the load 24 is possible via a specially attached to the load GPS receiver 30.

In the FIG. 1 A denotes the projection of the load 24, which can be determined very accurately due to the GPS receiver.

In the FIG. 2 is in turn the schematic representation of the mobile crane superstructure 10 accordingly FIG. 1 played. Here are shown by the dashed lines possible deformations of the moving parts under load. In order to detect these deformations, prior art inclinometers have been arranged at various locations on the main boom 14, as indicated by reference numeral 32 in FIG FIG. 2 is clarified.

Finally, the clarifies FIG. 3 the displacement of the spatial position at the end of the jib 16 by the inclusion of the load 24. As shown here with reference to FIG. 3 becomes clear, moves the tip of the jib 16 on the one hand due to the displacement of the attachment point 34 of the main boom and on the other hand due to its own deflection. This composite displacement now no longer needs to be calculated, but can be detected directly by the GPS receiver.

Claims (9)

Crane, preferably a mobile or crawler crane, with a boom, with a control and with means for determining the position of different crane components, such as main boom, luffing jib, derrick boom, guy jib, derrick ballast and / or hook block,
characterized,
that these funds consist of recipients of a satellite-based system for global positioning. Crane according to claim 1, characterized in that the means consist of GPS receivers. Crane according to claim 1 or 2, characterized in that a reference receiver is arranged on the crane, to which the values of the remaining receivers can be related. Crane according to claim 3, characterized in that the reference receiver in the vicinity of the axis of rotation of the crane, preferably in the vicinity of the axis of rotation of the upper carriage of a mobile crane, is arranged. Crane according to one of the preceding claims, characterized in that the values derived from the receivers are wirelessly transferable to the controller. Crane according to one of the preceding claims, characterized in that in addition a receiver is arranged on the load. Crane according to one of the preceding claims, characterized in that via the controller, the data transmitted via the receiver data for determining the working area can be used. Crane according to claim 7, characterized in that the currently existing projection of the load is given directly to the controller for calculating the load torque limit. Crane according to claim 7, characterized in that from the recorded positions of the GPS receiver with their connecting lines an envelope around the crane can be generated and that the working space of the crane is provided with appropriate safety impacts monitorable.

Images