DE19721136A1 - Lifting system for heavy loads especially containers - Google Patents

Abstract

The load lifting system has damping compensating hydraulics to dampen pendulum movements and hold the stabilising cables taut. A 4-way current divider (25) in a 4-motor design with continuous shaft is mounted in outflow pipes (24a-24d) of piston cylinder units (15a-15c) and in front of a proportional pressure restricting valve (26) and releases similar amounts of hydraulic medium to the proportional pressure restricting valve for control. The 4-way current divider comprises four equal sized intercoupled hydraulic motors. During swing processes all four motors operate through the mechanical coupling against the pressure restricting valve so that the energy for turning the current divider is only applied by two damping cylinders.

Description

The invention relates to a load lifting system with a horizontal movable carrier, hanging lifting ropes, one Wear load-bearing device and at least one on the carrier arranged hoist winch. Between the hoist rope and the Load suspension device extend inclined against the vertical Stabilizing ropes on at least one with the hoist winch coupled stabilization cable drum can be wound up. Each Stabilizing rope is equipped with a piston-cylinder unit that acts as a tension and damping device acts connected. The hydraulic fluid in the Hydraulic chamber of the piston-cylinder unit is pulled by the associated stabilizing rope and is loaded with a damping and compensation hydraulic unit connected such that they have a a first high pressure set pressure relief valve against one smaller pressure can be emptied. The first pressure is on one to dampen Pendulum movements of the load suspension device desired rope force set. The second pressure is on one to hold the Stabilizing rope set sufficient rope strength. One under the second Pressurized pressure medium supply is via a to the hydraulic chamber opening check valve connected to this.

Such a load lifting system is from DE 29 54 274 and from DE 37 27 329 known. Through the stabilizing ropes and these assigned tensioning and damping devices should be achieved that pendulum movements of the load suspension device as a result of Accelerations and delays in moving the high-wire girder be eliminated quickly. The tensioning and damping devices at the known systems that run spatially or diagonally Vertical and horizontal forces. The horizontal forces act as Damping forces to avoid pendulum movements. The size of the Damping forces are specified by pressure relief valves. This Pressure relief valves are often designed and can be regulated different pressures according to the size of the loads and thus cause different damping forces.  

The damping cables or the effective damping forces act in the Usually symmetrically adapt to the oscillating load and form balanced Moments related to an exact center of gravity.

A disadvantage of all these known designs is that one off-center loaded container and therefore no longer in the middle Total load center different damping moments, related to the center of gravity, adjust and then during the commutes Rotational movements around the container vertical axis result. This Rotational movements adversely affect the stress on the Handling technology out and complicate or delay the exact Positioning the containers.

Another disadvantage of the known designs is that in one Lifting in certain operating conditions, d. H. if all four Damping cylinder against the resistance of the pressure relief valve be pulled out, the damping pressure only a certain size may reach so that the load handler with and without load does not hang in the damping cables. Then namely the hoisting ropes relieved and can jump off the rope pulleys.

It is an object of the invention to describe a load lifting system that off-center loaded containers without large and long-lasting pendulum and can turn rotary movements safely and quickly.

According to the invention the object is achieved in that a hydraulic 4-way current divider, which consists of four equal-sized and mechanical one below the other coupled hydraulic motors, there are between four damping cylinders from Piston-cylinder units and a common proportional pressure Limit valve is arranged. That flows during the commuting process damping medium ejected by two damping cylinders alternating between two motors of the current divider. Due to the mechanical coupling and the same swallowing volume flow exactly equal amounts from the damping cylinders. The piston rods of the Cylinders always travel the same way, regardless of different pressure conditions, which are characterized by different layers  of the overall focus. The flowing out of the flow divider Medium is controlled via a common pressure relief valve. Here too, the damping pressure upstream of the pressure relief valve is only to be chosen high enough to avoid hanging in the damping cables will, but by the arrangement of the current divider according to the invention generates higher damping pressures and thus higher damping forces, so that an oscillating load faster than in known systems for Standstill comes. During the commute work through the mechanical coupling all four hydraulic motors of the flow divider against that Pressure relief valve, using the energy to rotate the flow divider is only applied by two damping cylinders. Therefore increased the damping pressure in the two cylinders accordingly. At a Lifting movement is the pressure before the joint Pressure relief valve applied by four motors and then stands out lower and equal pressure values.

The invention is explained in more detail below using an exemplary embodiment explained. Show it:

Fig. 1 is a perspective view of an inventive load lifting system,

Fig. 2 is a plan view of the load lifting system according to the invention and

Fig. 3 shows a hydraulic circuit for the stabilization of the load lifting system.

The load lifting system shown in FIG. 1 contains a trolley 1 which can be moved in the direction of the double arrow 2 along a bridge girder. On the trolley 1 hoist rope drums 3 and 4 are attached, which are connected to each other by a synchronization shaft, not shown. Two hoisting ropes 5 a, 5 b and 6 a, 6 b each run from the hoisting rope drums to a load-carrying device 7 suspended in height by means of these hoisting ropes in the form of a so-called spreader for holding containers, specifically from the hoisting rope drums 3 , 4 via the spreader 7 attached deflection rollers 8 a, 8 b or 9 a, 9 b back to fixed points on the trolley 1 . At the fixed point of the lifting rope 5 b there is a load measuring device 38 for measuring the current rope load.

In order to prevent the spreader 7 suspended by the lifting ropes from swinging, there are additionally stabilizing ropes 10 a, 10 b, 10 c and 10 d, all of which emanate from a common stabilizing drum 11 , the stabilizing ropes 10 a and 10 c in a first and the stabilizing ropes 10 b and 10 d are wound onto the stabilizing drum 11 in a second opposite direction of rotation. The rope courses of the stabilizing ropes 10 a to 10 d correspond to each other, so that it is sufficient to follow the course, for. B. the stabilizing rope 10 a to describe. This stabilizing cable 10 a comes from the stabilizing drum 11 , via a first deflecting roller 12 a on the trolley, via a further deflecting roller 13 a on the trolley to a deflecting roller 14 a on the spreader 7 and then further to a piston-cylinder unit 15 a.

As can be seen from FIG. 2, all stabilizing ropes 10 a to 10 d run essentially diagonally to the plan of the spreader 7 . It is essential that -., Such as shown in Figure 2 a is identified by the stabilization line 10 - the rope 10 a of the pulley 13 a to the trolley to the piston-cylinder unit 15 a on the spreader 7 as large a horizontal Because it runs through, ie that the rope has the greatest possible inclination relative to the vertical. This strong inclination is essential for the stabilizing cables to perform their damping function.

. From Figures 1 and 2 it can be seen that the stabilization cables 10 a to 10 d in a position to obstruct lateral movements of the spreader in the direction of the double arrows 16 and 18 - will still be explained later - even to attenuate. Furthermore, as can also be seen from FIG. 2, the stabilizing cables are able to hinder and dampen torsional vibrations of the spreader 7 in the direction of the rotary arrow 17 .

From Fig. 1 it can also be seen that the stabilizing drum 11 is drivingly connected via a gear 19 to the hoisting rope drum 4 , which in turn - as already mentioned - is synchronized with the hoisting rope drum 3 via a shaft.

If the spreader 7 is lowered by slackening the lifting cables 5 a, 5 b, 6 a and 6 b, the stabilizing cables 10 a to 10 d are also reduced by coupling the rotary movement of the stabilizing drum 11 with the rotating movement of the lifting cable drum 4 . Now, however, the hoisting ropes run essentially vertically, while the stabilizing ropes are strongly inclined with respect to the vertical. This tendency leads to the fact that when the spreader 7 is lowered, the rope release of the stabilizing drum 11 coupled to the hoisting rope drum 4 does not exactly correspond to the additional rope requirement between the deflection roller 13 a and the deflection roller 14 a. The piston-cylinder unit 15 a provides the compensation. The diameter of the hoist rope drum 4 and the stabilizing drum 11 and the transmission ratio caused by the gear 19 have been chosen so that the length error of the stabilizing rope 10 a remains as small as possible and that this length error with a medium setting of the piston-cylinder unit compared to that tensioned rope distributed as evenly as possible on an excess rope and an insufficient rope.

The hydraulic piston diagram of FIG. 3 again shows the four piston-cylinder units from FIGS. 1 and 2, the following functional description essentially referring only to the piston-cylinder unit 15 a. The unit 15 a consists of a cylinder 19 a, a piston 20 a and a piston rod 21 a. The piston rod 21 a is, as can be seen from Fig. 1, connected to the end of the stabilizing rope 10 a, while the cylinder 19 a is attached to the spreader 7 . The annular space 22 a of the piston-cylinder unit 15 a is filled with hydraulic fluid. The other piston chamber 23 a is vented through a ventilation hole, not shown. From the annular space 22 a leads a line 24 a via the 1st chamber 25 a of the flow divider 25 to a proportional pressure relief valve 26 , at the output of which a line 27 is connected, which is connected to a pressure switch 28 and a pressure accumulator 29 , and returns via a check valve 30 a to line 24 a. Parallel to the proportional pressure relief valve 26 is a 4/2 way valve 36 , which is manually controllable, in series with a throttle 34 . The pressure accumulator 29 is connected to a safety pressure relief valve 31 , to which an emptying line 32 is connected in parallel to an unpressurized tank 33 . Finally, the pressure accumulator 29 is connected to a pump 39 which can be driven by a motor 35 and which maintains a certain pressure P1 in the pressure accumulator 29 . The level of this pressure P1, with which the annular space 22 a is also acted upon via the check valve 30 a, can be preselected by the pressure switch 28 . The setting is made so that a bias is given to the piston 20 a, which is sufficient to keep the stabilizing valve 10 a connected to the piston rod 21 a taut when the spreader 7 is not loaded.

The proportional pressure relief valve 26 is set to a minimum pressure P2 which, when the spreader 7 is not loaded, is higher than the pressure specified by the pressure switch 28 . The proportional pressure relief valve 26 is controlled by a load measuring device 38 , which in the illustrated embodiment is a strain gauge which is attached to the fixed point of the lifting cable 5 b and supplies electrical signals to the proportional pressure relief valve 26 , which is a measure of the load hanging on the spreader are so that the greater the transported load, the higher the limit at which the proportional pressure relief valve 26 opens.

To control the proportional pressure relief valve 26 , of course, other options can also be provided, for. B. a measuring device that measures the current consumption of the hoist motors and controls the proportional pressure relief valve 26 as a function thereof.

The components 25 to 36 represent a damping and balancing hydraulic unit, which works as follows: When the spreader 7 begins to oscillate, for example in Fig. 1 in the direction of arrow 37 , greater lengths of the stabilizing ropes 10 a are required, ie Stabilizing ropes 10 a and 10 b endeavor to pull the pistons 20 a and 20 b (see FIG. 3) to the left and thereby to reduce the annular spaces 22 a and 22 b. Since an outflow from the annular spaces 22 a and 22 b to the pressure accumulator 29 is blocked by the check valve 30 a and 30 b, an outflow can only take place via the proportional pressure relief valve 26 . However, this only opens at a minimum pressure which is greater than the pressure P1 and which is greater the greater the weight of the load, so that even with heavy loads the pendulum movement can be opposed because a pendulum movement is only permitted when the load-dependent pressure P2 at the proportional pressure relief valve 26 is exceeded.

The two motors 25 a and 25 b of the flow divider 25 are now driven due to the pressure drop that is established and, due to the rigid coupling, remove the same quantities from the cylinder spaces 22 a and 22 b. Consequently, the extension speeds of the piston rods 21 a and 21 b are the same. Because of the coupling of the four motors in the flow divider 25 , the motors 25 c and 25 d are also driven and likewise deliver equal amounts via the pressure limiting valve 26 . Now that all four motors work against the same pressure, the motors 25 c and 25 d have a braking effect due to the lower storage pressure, the rotational energy must be applied from higher pressures in the ring spaces 22a and 22b. These pressures are thus considerably above the values which are set upstream of the pressure relief valve 26 ; thus increased damping forces are effective. The hydraulic medium removed from the annular spaces 22 c and 22 d of the damping cylinders by the motors 25 c and 25 d is replenished by the storage circuit via the check valves 30 c and 30 d and is available for tightening the damping cables.

If the spreader 7 swings back against the direction of the arrow 37 in FIG. 1, the process described is reversed and the cylinder spaces 22 c and 22 d experience the corresponding damping forces. The process is repeated until the load has come to a standstill.

If, at the end of such an oscillation process, the spreader 7 assumes a position slightly out of the normal position against the direction of the arrow 37 and wants to return to its normal position, the stabilizing rope 10 a tries to prevent it from doing so. However, because of the only slight deflection of the spreader, the rope force in the stabilizing rope 10 a is no longer sufficient to build up the pressure P2 at which the proportional pressure relief valve 26 could open. In order nevertheless to enable the spreader 7 to return to its normal position, the 4/2-way valve 36 is present, which, for. B. can be opened by the crane operator by manual control, so that the pressure P2 to the lower pressure P1 is broken down and can flow back to the pressurized fluid from the annulus 22a into the pressure accumulator 29, until the spreader 7 to its normal position has been reached. The throttle 34 is used so that the pressure equalization does not take place suddenly and renewed pendulum movements are prevented.

When a stroke movement is initiated, phases can occur in which all four damping cylinders allow the medium to flow out against the resistance of the proportional pressure relief valve 26 . Now all four motors of the current divider 25 are driven, consequently the pressure in all four annular spaces drops to approximately the same values. These pressures are only slightly higher than the pressure set at the proportional pressure relief valve 26 .

Reference list

1

Trolley

2nd

Direction of travel

3rd

,

4th

Hoist rope drum

5

,

6

Hoist rope

7

Load suspension device, spreader

8th

,

9

Pulley

10th

Stabilizing ropes

11

Stabilizing drum

12th

,

13

,

14

Pulley

15

Piston-cylinder unit

16

,

17th

,

18th

Movement of the spreader

19th

transmission

19th

a cylinder

20th

a piston

21

a piston rod

22

a annulus

23

a piston chamber

24th

a line

25th

4-way flow divider with the chambers

25th

a,

25th

b,

25th

c and

25th

d

26

Proportional pressure relief valve

27

management

28

Pressure switch

29

Pressure accumulator

30th

check valve

31

Safety pressure relief valve

32

Drain line

33

pressureless tank

34

throttle

35

engine

36

4/2-way valve

37

Pendulum movement of the spreader

38

Load measuring device

39

pump
P1 pressure in the accumulator

29

P2 adjustable minimum pressure of the proportional pressure relief valve

Claims (2)

1. Load stroke system with a damping and balancing hydraulics for damping pendulum movements of a load suspension device and for tensing stabilizing cables, characterized in that in drain lines ( 24 a, 24 b, 24 c, 24 d) of piston-cylinder units ( 15 a , 15 b, 15 c, 15 d) and in front of a proportional pressure relief valve ( 26 ) a 4-way flow divider ( 25 ) in 4-motor design with a through shaft is arranged, the same amount of hydraulic fluid to the proportional pressure relief valve ( 26 ) releases for control. 2. Load lifting system according to claim 1, characterized in that the 4-way current divider consisting of four equal-sized, interconnected Hydraulic motors exist.