The invention concerns a lifting apparatus, in particular a ferry landing stage, comprising a platform which may be taken into a predetermined lift position by means of a drive mechanism.
The like lifting apparatus are employed, e.g., in a ferry landing stage installed on a quai, the platform or ramp (link span) of which is linked to the quai by one end portion thereof while the other end portion is aligned, relative to the floor of the hold of the ferryboat, with the aid of hydraulic cylinders so that the vehicles may move into and out from the ferry. Customarily two parallel hydraulic cylinders are used for rotating and supporting the ramp. Owing to malfunctions in the electrical, mechanical or hydraulic systems, skewing of the ferry landing stage may occur, which in the least favorable case results in breakage of one end of the drive mechanism.
The invention is therefore based on the objective of furnishing a lifting apparatus, in particular a ferry landing stage, wherein a risk of damages is prevented at minimum expense.
This objective is attained by a lifting apparatus having the features of claim 1.
The lifting apparatus of the invention comprises a platform which is capable of being taken into a predetermined lift position by means of a drive mechanism, e.g., a hydraulic cylinder. In accordance with the invention a safety stop acting in parallel with the hydraulic cylinders is associated with the drive mechanism, so that reliable supporting is ensured even in the event of breakage in the drive mechanism.
From the prior art in accordance with DE 38 11 225 A1 a safety stop is known per se, however the latter directly acts on the piston rod of a hydraulic cylinder. In the event of a breakage of a piston rod as described above, however, such a safety stop cannot take effect, for which reason it dos not satisfy the safety requirements to be underlaid, e.g., for ferry landing stages.
In a particularly preferred variant of the invention, the safety stop is designed to include a stop rod capable of being connected to the platform via clamping means similar to those of DE 38 11 225 A1. I.e., in the event of irregular movement of the hydraulic cylinders or of some other hazard, the lifting apparatus engages the clamping means so that the platform may be decelerated and immobilized independently of the drive mechanism.
Here it is particularly preferred if the clamping device has a clamping cylinder through which the stop rod extends and in which clamping members are guided in a slidable manner, which clamping members are hydraulically biased into a release position and may be taken into clamping engagement with the stop rod.
Operational safety of the lifting apparatus of the invention may be further improved if the clamping members are received in a clamping piston which is accommodated in the clamping cylinder in an axially slidable manner. In accordance with the invention, the clamping piston is hydraulically biased into a basic position. In the event of a hazard to the lifting apparatus, the clamping device is engaged and moves against the hydraulic biasing pressure. Through a defined stopping distance the kinetic energy of the lifting apparatus is neutralized without any damage to the entire installation.
This maximum pressure is preferably limited with the aid of a pressure control valve through which the cylinder space may be connected to a tank.
The clamping members of the clamping means are, preferably by hydraulic means, biased into their release positions, such biasing being obtained with the aid of one or several actuating pistons guided in the clamping piston, the rear face(s) of which is/are subjected to an actuation pressure.
It is particularly advantageous if this actuation pressure corresponds to the pressure acting on the entrance side of the pressure control valve.
Driving the clamping members, i.e. engaging the clamping members, is achieved by switching a switching valve whereby the tank pressure may be applied to the rear faces of the actuating pistons for engagement, so that the clamping members are moved mechanically, such as by the force of a spring, into their clamping positions.
In a particularly preferred embodiment, a path measuring system is associated to the safety stop, whereby the path and the velocity of movement of the clamping cylinder relative to the stop rod may be detected. When the detected signals exceed predetermined limit values, the safety stop is driven, so that the clamping members engage and the platform is braked.
The pressure for operability of the safety stop is advantageously built up with the aid of a pump associated with a hydraulic reservoir in the system. This has the purpose of avoiding pressure peaks when the safety stop responds.
In a particularly compact variant, the above described hydraulic components and/or a pressure medium tank are integrated into the housing of the clamping cylinder or flange-mounted on the latter.
Other advantageous developments of the invention are subject matters of the further subclaims.
Hereinbelow a preferred embodiment the invention shall be explained in more detail by referring to schematic drawings, wherein:
In
Insofar the represented ferry landing stage 1 corresponds to conventional solutions. If, now, breakage of one of the piston rods 14 occurs owing to skewing, then the ramp 2 may crash in an uncontrolled manner or at least be badly damaged by the torsional forces involved.
In order to prevent such damages to the platform 2, a safety stop 20 by which the platform 2 may be braked and supported independently of the action of the hydraulic cylinders 8, 10 is associated with the hydraulic cylinders 8, 10. In the represented embodiment the safety stop 20 consists of two stop rods 22, 24 supported on the ground side and each extending through one clamping cylinder 26, 28 which is capable of being taken into clamping engagement with the stop rods 22, 24. This safety stop 20 shall in the following be explained in more detail by referring to
In accordance with
In the cylinder housing 32 a clamping piston 40 is guided in an axially slidable manner, which clamping piston is biased into a lower stop position by the pressure in the cylinder space 38 located on top in
As is represented on the right side in
The hydraulic components for driving the clamping cylinder 26 are essentially integrated into a secondary housing 52 fastened on the cylinder housing 32 or formed in the latter.
In the described embodiment, the stop rods 22 have a standing arrangement. As the clamping cylinder 26 is fixedly connected with the platform 2, the stop rods 22 have to be supported on the quai wall or an a dolphin with the aid of a support bearing 53, so that the clamping cylinder 26 may be moved along the stop rod 22 without any jamming.
The hydraulic components of the clamping cylinder 26 shall be explained in more detail by referring to
As is evident from the representation on the right side in
In the represented basic position of the switching valve 66, which is reached, by driving a switching solenoid, the connection passage 64 communicates with a pressure passage 68 leading to a hydraulic reservoir 70. For switching, the switching solenoid is deactivated, so that the switching valve 66 is taken by the force of a compression spring into its second switching position wherein the connection passage 64 is connected with the tank.
From pressure passage 68 a line 72 branches off which leads to a radial port 74 of the cylinder space 38. In other words, the pressure in the hydraulic reservoir 70 also acts on the end face of the piston located on top in
The pressure in the pressure passage 68 may be limited to a predetermined maximum pressure with the aid of a pressure control valve 82. When this maximum pressure is exceeded, the pressure passage 68 is connected to the tank T through the pressure control valve 82.
As is moreover evident from
As is moreover indicated in
During normal operation of the ferry landing stage, for example during retraction of the hydraulic cylinders 8, 10 for lifting the ramp 2, the switching valve 66 is in its basic position represented in
For the sake of completeness it should be mentioned that a path measuring system 84 is integrated in each one of clamping cylinders 26, 28. In the case of a nonuniform movement of the two hydraulic cylinders 8, 10, different position and velocity signals are output by the two path measuring systems 84 of clamping cylinders 26, 28. When a predetermined limit value is exceeded, an actuation signal is emitted by the control 86 to the switching valve 66, so that the latter is switched by the force of its compression spring into the other switching position in which the connection passage 64 is connected with the tank T. I.e., the pressure in the actuation space 54 is relieved towards the tank T; the clamping members 44 may then be shifted into their engaging positions (on the left in
When the brake is being engaged, the pressure in the cylinder space 38 prevents further acceleration of the load. Owing to the dynamic load, the clamping piston 40 moves into the cylinder space 38. This results in a pressure rise in the cylinder space 38, bringing about a deceleration of the load to a final standstill.
In order to prevent an overload on the ramp 2, the pressure in the cylinder space 38 is limited to a maximum pressure with the aid of the pressure control valve 82. When this pressure is exceeded, the pressure medium in the cylinder space 38 is relieved towards the tank.
The hydraulic reservoir 70 is designed to have a comparatively large volume, so that pressure peaks during the deceleration process may be attenuated. The system is designed such that the maximum braking force may be applied within about 100 msec. For the purpose of limiting the braking force to the maximum value, a quick response of the pressure control valve 82 is necessary. In order to be able to realize the time for building up the maximum braking effect, it is necessary for the pressure control valve 82 to completely open the connection towards the Tank T within approximately 5 msec.
In the embodiment represented in
Instead of the standing arrangement of the stop rods 22, 24 it is, of course, also possible to choose a suspended arrangement in kinematic reversal.
In the above described embodiment, hydraulic cylinders 8, 10 are employed for rotating the platform 2. Instead of these hydraulic cylinders it is also possible to use other drive mechanisms, e.g. cable winches, spindles, etc.
What is disclosed is a lifting apparatus, in particular a ferry landing stage, comprising a platform that is capable of being taken into a predetermined lift position with the aid of at least one drive mechanism. A safety stop by which the platform may be supported independently of the drive mechanism is associated to the drive mechanism.
Number | Date | Country | Kind |
---|---|---|---|
101 36 284 | Jul 2001 | DE | national |
101 63 691 | Dec 2001 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP02/07437 | 7/4/2002 | WO | 00 | 2/24/2004 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO03/010387 | 2/6/2003 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2886228 | Susikari | May 1959 | A |
4531248 | Swessel et al. | Jul 1985 | A |
4862547 | Alten | Sep 1989 | A |
4968182 | Westwell | Nov 1990 | A |
5184914 | Basta | Feb 1993 | A |
5378082 | Hiller et al. | Jan 1995 | A |
5440772 | Springer et al. | Aug 1995 | A |
5632357 | Matre | May 1997 | A |
6276016 | Springer | Aug 2001 | B1 |
6820295 | Webster | Nov 2004 | B2 |
6931686 | Hoofard et al. | Aug 2005 | B2 |
20030226222 | Stolk | Dec 2003 | A1 |
Number | Date | Country |
---|---|---|
33 44 123 | Jun 1985 | DE |
37 30 363 | Dec 1988 | DE |
3811225 | Oct 1989 | DE |
38 40 096 | May 1990 | DE |
39 15 304 | Nov 1990 | DE |
1 442 983 | Jul 1976 | GB |
Number | Date | Country | |
---|---|---|---|
20050029053 A1 | Feb 2005 | US |