DE29924989U1 - Continuously adjustable crane - Google Patents

Abstract

Crane with an undercarriage which rotatably supports a superstructure about a vertical axis, a ballast element (6, 7), a boom which is mounted on the superstructure about a horizontal axis, the boom having a plurality of jib elements (1, 2) which are movable relative to each other, a plurality of moving devices each for moving one of the boom elements (1, 2), sensors (4, 5) for determining the respective instantaneous position of the boom elements (1, 2) and a control device for controlling said movers,
the control device being connected to the sensors (4, 5) and determining allowable carrying loads of the crane for the different positions of the jib elements (1, 2) in accordance with the sensor signals,
the control device comprising means for simultaneously actuating under load at least two moving devices moving the respective jib elements (1, 2),
wherein the control device has a computing unit (CPU) for determining the respective permissible load for each of the positions of the boom elements (1, 2) at the same time.

Description

The The invention relates to a continuously adjustable crane.

Around To ensure the operational safety of a crane are for certain Positions of the crane main boom Crane limit data determined. Based this data for the carrying capacity it can be determined which load is picked up by the crane can not get into a critical operating condition. Should he Crane can be used in a different configuration, so in the load-free state of the main boom of the crane in a different position proceed, for which corresponding crane limit data are available. In this position the crane can then be put into operation again, by means of the for This state existing data can be ensured that no critical loads on the crane occur. So it is e.g. at known cranes with tilting accessories usual that the main boom of the crane in one or more fixed rocker positions with each associated fixed stored limit curves is operated.

It The object of the invention is the scope of a known Crane to enlarge.

These Task is solved by a crane according to claim 1. advantageous Embodiments result from the dependent claims.

According to the invention, two Boom elements, in particular a rocker and / or telescopic main boom as well as an independent from the main boom adjustable luffing jib, at the same time under Load are adjusted, wherein the control device is a computing unit for the determination of the respectively permissible Load capacity for each of the positions of the boom elements simultaneously with their movement under load and wherein the control device comprises a monitoring unit for Cancel the operation the boom movements then, if that of the arithmetic unit respectively certain permissible Load capacity reached and / or exceeded is, has. This is when adjusting the crane under load in particular a limit curve or limit data for the permissible load specified in at least one rocking position of the crane jib. These Data indicates which loads the crane is in the specific rocking position can be subjected. From one or more of these predetermined Limit curves for each a certain rocker position of a crane jib will be for more Rocker positions of the crane jib possible permissible load conditions or load limit values calculated, which in a continuously tiltable crane boom for every indicate individual rocking position, how big are the respective loads may be. This makes it possible to rock a crane boom continuously even under load for this each individual rocking condition the respective carrying capacity limits can be determined. With the crane according to the invention the crane operator can load by any rocking, e.g. of the main boom or the luffing boom over the entire working radius. there is a simultaneous rocking in particular of main boom and Luffing jib possible.

So is it possible, for example, that main boom and luffing jibs from their steepest operating position, e.g. Main boom angle = 87 °, point angle = 77 °, under Load in the flattest operating position, e.g. Main boom angle = 67 °, point angle = 10 °, moved be determined using the method according to the invention in each case can be how big the maximum permissible Load capacity of the crane. There is no need for one an overload protection permanently set crane state, so that during the entire rocking operation e.g. always a load capacity indicator and load monitoring carried out can be. From the for different positions of the crane boom stored load limits for different Positions of a crane boom, such. of the main boom, and The current position of the main boom can be used to set new load limits for the current boom Main boom position are calculated.

Advantageous at least one limit curve is provided for a boom position, being natural also possible is a larger number on exposure limits, each for a particular position of a Crane boom, such. of the main boom to store firmly. Out of or for a or several rocker positions of the crane jib stored data can then by suitable calculation methods, e.g. Interpolation or Extrapolation, for every condition of the crane, i. any tilt angle of the main boom or the jib or counterjib, the load limits for the respective positions are calculated.

At The crane sensors are arranged with which the current Position or configuration of the crane can be determined. For this can e.g. an angle encoder on the main boom to capture the current Main boom position be provided. It's the same, of course possible a corresponding sensor for to provide the luffing jib. It is also possible to provide other sensors, such as. Load sensors or position sensors with which the instantaneous Location of the or each crane boom, in particular their rocker or Tilt angle, can be determined.

The signals picked up by the sensor or sensors are used to determine the current position of a crane jib, for which the applicable overload limits to be determined.

there become the possible ones Load capacities for every operating position of the main boom, so that in a continuous Rockers of the main boom for each position load limits for the Crane can be determined. Naturally it is also possible to apply this jointly to luffing jib and main jib, so that both can be tilted under load, being always a load monitor he follows. This is also possible with a counter-jib. Insbeosndere any crane boom, such as the main boom, stepless be adjusted under load.

Farther An adjustable ballast element can be provided with which be ensured especially when attached to a crane boom load can that the Ballast or the current position of the ballast the current Loading condition of the crane corresponds. If e.g. the main boom Steplessly tilted under load, so can by a corresponding stepless simultaneous adjustment of the ballast element one for each Operating condition exactly coordinated ballast done. By a continuous adjustment of the ballast element can be ensured be that for everyone Wippzustand of the crane boom or a coordinated or optimal counter ballasting done. The ballast element has preferably a variable one Distance to the lower rocker axle or the revolving platform of the main boom.

When steplessly adjustable ballast element can e.g. a counter or Derrickausleger be provided on which a ballast element is attached. To design the counter ballast stepless, the derrick boom can either steplessly tilted or e.g. also telescoped become. Should e.g. a crane with a main boom and possibly a luffing jib under load from a steep operating position into a flatter one Operating position can be brought, so can e.g. to the coordinated Counterbalancing the derrick also from a steep be brought into a shallower operating position by the the ballast element acting on the main boom or the revolving stage Counter load by enlargement of the Lever to enlarge.

As well it is also possible the ballast element on a float or ballast wagon e.g. With controllable wheels provide, wherein the ballast element in the horizontal direction preferably continuously can be extended, so that by a corresponding method or telescoping the ballast element for the current load condition of the crane a matched ballast can be done.

there it is advantageous at least one sensor element for detecting the provide current configuration of the crane. This can, as already described above, e.g. Angle encoder on the respective crane jib be provided for detecting the operating state. Likewise, appropriate Sensor elements e.g. on the derrick or the ballast element be attached, which determine the current position of the ballast element can.

at the above crane designs is it is advantageous to load monitoring to provide for each crane condition and the currently lifted load is monitored, that the Crane is still in a safe operating area. As with the stepless Adjustment of or the individual crane boom or the ballast element for each Operating condition at any time the applicable load limits calculated it is also during the rocking of the crane from a first position to a second position Position possible, each determine whether the currently occurring load is still within the permissible range lies or where the limits of the maximum permissible load of the crane lie. This can, as stated above, by the use of load limits or a limit curve for a fixed predetermined state of the crane done by a calculation method, e.g. Interpolation or extrapolation for every Configuration of the crane, i. any rocking angle of the or the single crane boom, a limit curve or suitable load limits can be determined.

It It is advantageous to display the calculated maximum allowable load, it being equally advantageous that the momentarily occurring load, e.g. is measured by means of a load sensor is shown. This allows it to a crane operator or a suitable controller to assess how large the safety reserves crane are still.

The control device for adjusting the crane under load has sensor elements with which data relating to the instantaneous position of the crane can be determined. Thus, for example, by means of an angle encoder on the main, top or derrick boom the respective current positions are detected, whereby load sensors or position sensors, eg for a continuously variable ballast, can be provided. Each of the mentioned sensors can be provided individually or in combination with one or more other sensors on the crane. The signal or signals detected by the sensor element become a computing unit transfer. Furthermore, a memory unit is advantageously provided in the control device, in which at least one data set for load limit values or corresponding load limit values for a fixed configuration or rocking position of the crane can be stored. The memory unit is connected to the mentioned arithmetic unit, so that the arithmetic unit can calculate the current load capacity for the respective operating state of the crane with the aid of the data stored in the memory unit data for the load limits and using the sensor data for determining the current configuration of the crane. The calculated data can then either be output for the crane operator via a suitable output device, eg for displaying the current load in relation to the calculated load capacity, or fed to a crane control, which prevents the crane from entering a critical operating state.

It is so sufficient for only one configuration of the crane, i. corresponding rocker positions single boom, permissible Crane limit data for the burden available to ask from this record using appropriate arithmetic operations the load limit data for Any other operating condition can be determined without individual fixed preset states have to be set beforehand. It can also be provided that the ballast on the each crane state is tuned so that for each lifted or to be lifted Load a correspondingly suitable position of the ballast element set can be.

So can a crane operator by any adjustment of the ballast position, such as. Extracting and retracting the ballast in the entire ballast radius range, the ballast element e.g. from a smallest predetermined ballast radius from e.g. 11 m to the largest predetermined Ballast radius of e.g. Move 15 m, with always a load monitoring or load capacity indicator for the respective operating state of the crane can take place.

For one certain crane equipment condition can e.g. For one or more Ballastnennstellungen limit curves specified be, from the predetermined load limits and by means of of a sensor determined current position of the ballast new Load limits for the current ballast position can be calculated.

The Invention will be described below with reference to figures. Show it:

1 a crawler crane with main boom;

2 a crawler crane with main and counter (derrick) outriggers;

3 a crawler crane with main and luffing jib;

4 a crawler crane with main, apex and counter (derrick) outrigger;

5 a mobile crane with a main, apex and counter (derrick) outrigger; and

6 a mobile crane with telescopic head, apex and counter (derrick) outrigger

7 a block diagram of the device according to the invention.

1 shows a crawler crane with a main boom 1 , which can be tilted continuously in the direction of the arrow from its steepest position shown to a shallower position, wherein in each rocking state of the main boom 1 the applicable load limits can be determined. There is a ballast element on the crane 6 provided which can be moved continuously in the horizontal direction as shown by the double arrow to a coordinated position of the ballast element for each main boom position 6 adjust. In this case, the position of the ballast element 6 also depending on one of the main boom 1 be set recorded load, for example, a load sensor 5 at the head of the main boom 1 can record appropriate data.

2 shows a caterpillar crane with main boom 1 and counter-stirrup or jib 3 , which can be adjusted independently of each other continuously, wherein the adjustment of the main boom 1 the position of a recorded load can be changed and the associated ballasting via an adjustment of the derrickauslegers 3 can be made. In this case, the ballast element 6 as in 1 shown to be telescoped in a horizontal direction. The ballast element 7 can be telescoped either in a horizontal direction or on the derrick boom 3 be attached over a rope, the derrick 3 in the direction indicated by the arrow can be tilted. It is also possible only a single ballast element 6 or 7 provided.

3 shows a caterpillar crane with main boom 1 and luffing jib 2 , which are both infinitely adjustable under load. The main boom 1 can work together with the luffing jib 2 from the in 3 shown steepest operating position with recorded load in a shallower operating position are tilted, at the same time main boom 1 and luffing jib 2 be tipped. In order for the respective recorded load a corresponding Bal Lasting provide, the ballast element 6 For example, in a horizontal direction infinitely retracted and extended or telescoped.

4 shows a caterpillar crane with main boom 1 , Luffing jib 2 and derrick 3 which can be adjusted independently of each other and at the same time, wherein the angular position of the main boom 1 and the top jib 2 the position of the load can be changed and the angular position of the derrick boom 3 a corresponding ballast can be done. As described above, the ballast element 6 be adjusted and the ballast element 7 hanging on the derrick boom 3 be provided, or be telescoped accordingly to be telescoped away from the viewpoint of the crane or einteleskopiert to the point of view. On the arms are angle encoders 4 . 4 ' and at the jib 2 a load sensor 5 intended. The sensors 4 . 4 ' and 5 can be installed at any suitable position.

5 shows a mobile crane with lattice boom in similar configuration as 4 wherein the ballast element can be adjusted as described above.

6 shows a mobile crane with telescopic boom in similar configuration as in 5 , wherein the ballast element 6 . 7 can be adjusted as described above.

Although adjusting the ballast elements 6 and 7 has been described above together with the stepless adjustment of the individual crane boom, a continuously variable ballast element may be provided in any known crane. The counter ballast can, even under load, be brought to a suspension hanging in the desired position, as well as a suspended ballast or ballast preferably stepless retracted or extended or telescoped.

It is also possible stepless rocking of the individual or crane jib, such as the main boom 1 to use with the simultaneous calculation of the respective limit load conditions in a known crane, without making the ballast infinitely adjustable.

7 shows a block diagram of a control device of a crane according to an embodiment of the invention. In this case, data for one or more defined configurations or positions of a crane are stored in a memory, with which the respective permissible limit loads can be determined. For example, a data record is stored in the memory, which in a crane according to 4 for a given first position of main boom 1 , Luffing jib 2 and derrick 3 indicates which loads can be picked up. Such a data record can also be stored for a second position of the crane. If the crane moves steplessly into a certain position, the respective positions and possibly load states of the individual crane jibs are transmitted to a computer CPU via corresponding sensors, such as angle sensors and load sensors, which take into account the data sets stored in the memory, the new limit load data of the Cranes calculated so that the data can be output to an overload protection or a display. Furthermore, the crane operator can enter data into the CPU via a console which can be used to calculate the limit load data by the CPU.

Claims (10)

Crane with an undercarriage which rotatably supports a superstructure about a vertical axis, a ballast element ( 6 . 7 ), a cantilever mounted on the uppercarriage about a horizontal axis, the cantilever having a plurality of cantilever elements ( 1 . 2 ), which are movable relative to each other, a plurality of moving devices each for moving one of the boom elements ( 1 . 2 ), Sensors ( 4 . 5 ) for determining the respective instantaneous position of the jib elements ( 1 . 2 ) and a control device for controlling said movement devices, wherein the control device with the sensors ( 4 . 5 ) and permissible loads of the crane for the different positions of the jib elements ( 1 . 2 determined according to the sensor signals, wherein the control device comprises means for simultaneously actuating at least two of the corresponding jib elements ( 1 . 2 Moving devices under load, wherein the control device comprises a computing unit (CPU) for determining the respective permissible load for each of the positions of the boom elements ( 1 . 2 ) at the same time as movement thereof under load, and wherein the control device has a monitoring unit for stopping the actuation of the movement devices when the permissible load determined by the arithmetic unit is reached and / or exceeded. Crane according to the preceding claim, wherein the at least two cantilever elements which are simultaneously movable under load by the control device ( 1 . 2 ) a rocker and / or telescopic main boom ( 1 ) and one independent of the main boom ( 1 ) adjustable luffing jib ( 2 ). Crane according to one of the preceding claims, wherein the ballast element ( 6 . 7 ) from the control device simultaneously to the jib elements ( 1 . 2 ) of the crane under load in its ballast radius is adjustable. Crane according to one of the preceding claims, wherein the ballast element ( 6 . 7 ) depending on the load condition of the crane and the position of the jib elements ( 1 . 2 ) is adjustable in its ballast radius under load of the crane, a sensor for determining the ballast radius is provided, and the control device on the basis of the respectively determined ballast radius and the respective position of the boom elements ( 1 . 2 ) the permissible load of the crane at the same time as the simultaneous adjustment of the jib elements ( 1 . 2 ) and the ballast element ( 6 . 7 ) under load. Crane according to one of the preceding claims, wherein the control device has a memory in which limit loads for at least two rocking positions of the boom elements ( 1 . 2 ), and the arithmetic unit determines the boundary loads for intervening or adjacent positions by interpolation and / or extrapolation. Crane according to one of the preceding claims, wherein the sensors ( 4 . 5 ) for determining the position of the jib elements ( 1 . 2 ) consist of an angle sensor, a load sensor and / or a position sensor. Crane according to one of the preceding claims in conjunction with claim 2, wherein the computing unit permissible limit loads over the entire rocker area of the main boom ( 1 ) and the entire rocker area of the luffing jib ( 2 ) relative to the main boom ( 2 ) certainly. Crane according to one of the preceding claims, wherein the control device is designed such that the jib elements ( 1 . 2 ) are steplessly adjustable under load. Crane according to one of the preceding claims, wherein the horizontal distance between the at least one ballast element ( 6 . 7 ) and a lower luffing axis of the boom ( 1 ) is infinitely adjustable. Crane according to one of the preceding claims, wherein the at least one ballast element ( 7 ) on a counter-jib ( 3 ) is attached.