The invention relates to a lifting device for lifting objects, particularly motor vehicles, comprising a main lifting unit and an additional lifting unit, wherein a single hydraulic set comprising corresponding control members may be used in order to reduce the necessary measuring and control means for the overall lifting unit which may consist of a main lifting unit and an additional lifting unit.
Lifting devices having a main lifting unit and an additional lifting unit are known on the market. Such lifting units may on the one hand be scissors or pantograph lifting platforms, as shown e.g. in
In all lifting devices known so far, the main lifting gear and the additional lifting gear are driven cascadedly, which results in an overall lifting height larger than the lifting heights of the individual lifting gear. Here, the main lifting gear is lifted at first and then the additional lifting gear is extended. Commercially available lifting platforms have two travel or running rails onto which a vehicle may be moved. In this case, for each running rail a respective pantograph lifting platform is used, for example, in order to guarantee sufficient accessibility to the vehicle floor. No mechanic connection members are provided between the two pantograph lifting platforms. As these pantograph lifting platforms can be lifted independently of each other, it is therefore necessary from a technical point of view to take the lifting height of the two running rails (left and right running rail) to the same level and permanently maintain them there.
In this connection, various solutions have so far been known on the market. One possibility consists of so-called master/slave systems wherein only one cylinder of e.g. the left half of the vehicle is pressurized with oil by the hydraulic set. The oil displaced in the cylinder rod chamber is connected to the piston chamber of the right half of the vehicle. Now, if the piston volume of the right half of the vehicle and the rod volume of the left half of the vehicle have the same dimension, a compulsory synchronicity of the lifting gears is achieved. Such technology is used in main lifting gears and additional lifting gears alike.
Here, the problem turns up that comparatively great cabling and piping efforts are required. Also, the electronics of the hydraulic system prove to be very difficult. Furthermore, means must be provided so that small leakages on the cylinders may be compensated.
In addition thereto, techniques are known which use an electro-hydraulic synchronization control. Here, the ways of the main lifting unit and the additional lifting unit are detected via electric measuring units. The lifting platform is supplied with oil via a so-called flow divider and a pressure regulator, respectively, the flow divider providing a rough synchronization of the two lifting platform parts. However, in case of unequal load distribution, height differences result which must be evened out. For this purpose, the signals generated by the electronic masters are compared and corresponding hydraulic actuators are driven to even out the lifting heights. The hydraulic control members, like the electrical measuring units, are respectively required for the main lifting and the additional lifting units. To this end, electric measuring units are required on the two main lifting units and the two additional lifting units. Furthermore, all controls must also be realized in duplicate.
This leads to the disadvantage that correspondingly high technical efforts are necessary and that moreover the installation of such lifting platform turns out to be correspondingly laborious.
It is the object of the invention to provide a lifting device for lifting objects, in particular vehicles, which makes do with as few measuring means and control means as possible.
This object is achieved by a device and a method comprising the features of the independent claims. The dependent claims relate to advantageous developments of the invention.
The inventive lifting device for lifting objects, particularly motor vehicles, may comprise at least one main lifting unit and/or at least one additional lifting unit. The additional lifting unit may be disposed on the main lifting unit in such a way that a main lifting height of the lifting platform may be extended to a total lifting height by using the additional lifting unit. Furthermore, a control unit may be provided which is characterized in that both the main lifting unit and the additional lifting unit may be driven by the control unit. Moreover, at least one main actuator and at least one additional actuator may be provided, the main actuator and the additional actuator being switchable in dependence upon each other in such a manner that alternatively only the main actuator or the additional actuator is transferable into an active or activated state. By using a single control unit for both lifting units, it is possible to reduce the cabling efforts in a particularly simple manner and thus the accessibility beneath an object to be lifted may be improved. Moreover, the advantage results that the number of components may be reduced. Furthermore, a measuring unit may be provided by means of which the total lifting height resulting from the sum of the main lifting height of the main lifting unit and the lifting height of the additional lifting unit are jointly determinable. For this reason, it is possible to further reduce the number of components used.
In this case, the control unit may be a control unit and/or controller and the main actuators and additional actuators may be in the shape of seat valves.
The lifting units may be operated hydraulically and/or electrically. The lifting units and the lifting device, respectively, may be subsurface platforms comprising plungers or cylinders, column lifting platforms, each possibly also comprising a telescopic operation, and/or swiveling lifting platforms.
Furthermore, the main actuator may be transferable into an open or active state in which the main lifting unit may be driven, and into a closed or inactive state in which the main lifting unit cannot be driven, and/or the additional actuator may be transferable into an open or active state in which the additional lifting unit may be driven, and into a closed or inactive state in which the additional lifting unit cannot be driven, wherein, when the main actuator is in an open or active state, the additional actuator is only transferable into a closed or inactive state, and/or when the additional actuator is in an open or active state, the main actuator is only transferable into a closed or inactive state. Thus, it can be ensured that the individual lifting units cannot be operated at the same time and thus the risk of an erroneous detection of synchronization by the control unit is excluded although the lifting units perform uneven lifting movements.
In one embodiment the lifting device may be hydraulically operated. In this case the control unit may for example be a hydraulic control unit having a flow distributor or divider and two by-pass valves wherein alternatively a synchronization control of the main lifting units or the additional lifting units may be performed by means of the control unit.
Furthermore, if a lifting difference exceeds a first limiting value, a by-pass valve of the respective higher main lifting unit and/or additional lifting unit may be transferable into an opened state for a limited time. Thus, the advantage results that slight lifting differences can be compensated between the respective lifting units of a running rail with respect to the other running rail without interrupting the lifting movement of the lifting platform.
Moreover, if the lifting difference exceeds a second limiting value, a first lock valve may be transferable into a closed state in addition to opening the by-pass valve. Thus, a lifting difference between the lifting units can be compensated in a particularly simple manner, the compensation being achieved faster than in the case that only the by-pass valve of the respective higher lifting unit is opened for a limited time.
Furthermore, if the lifting difference exceeds a second limiting value, a second lock valve may be transferable into a closed state in addition to opening the by-pass valve. Thus, the advantage results that if a lifting difference occurs, this lifting difference may be compensated by using the main lifting unit as well as the additional lifting unit.
Moreover, if the lifting difference exceeds a maximum value, the lifting device can be shut down by the fact that all lock valves are transferable into a closed state and a pumping set can be put out of operation. This offers the advantage that in case an inadmissible lifting difference between the lifting platforms occurs, the entire system can be switched off, while it can be ensured that an object located on the lifting unit, such as, for example, a motor vehicle, can be prevented from falling off.
Furthermore, the lifting device may be characterized in that at least one measuring unit per lifting member is provided, the lifting member possibly comprising a main lifting unit connected to at least one additional lifting unit, wherein a total lifting height resulting from the sum of the lifting height of the main lifting unit and the lifting height of the additional lifting unit may be jointly determinable. Thus, the advantage results that the number of components may be further reduced because it is only the position of the additional lifting units to each other that is exclusively decisive for the safe support of the object to be lifted. If the additional lifting unit is not used but the motor vehicle is lifted only by the main lifting unit, the additional lifting unit is respectively positioned on the main lifting unit and can provide information on the height of the main lifting unit by measuring the distance from the floor surface to the additional lifting unit. Thus, it is no longer necessary to provide additional sensors on the main lifting units.
Moreover, the lifting device may be characterized in that the measuring unit is formed by a contact-free measuring means and that the lifting height between a floor surface and the additional lifting unit is detected whereby the total lifting height of the lifting platform is directly determinable.
Furthermore, the lifting device can be characterized in that the measuring unit is formed by a cable pull sensor, the cable pull sensor being attached to the floor and a pull-out cable being connected to the additional lifting unit.
Furthermore, a lifting device may be characterized in that the measuring unit is formed by a cable pull sensor, the cable pull sensor being attached to the additional lifting unit and the pull-out cable being connected to the floor.
Moreover, the lifting device may be provided for lifting objects, particularly motor vehicles, which comprises at least one main lifting unit and/or at least one additional lifting unit. In this case, the additional lifting unit may be disposed on the main lifting unit in such a way that a main lifting height of the lifting platform is extendable by using the additional lifting unit to a total lifting height. Furthermore, control means may be provided for controlling the main lifting unit and the additional lifting unit. Furthermore, at least one measuring unit may be provided with which a total lifting height resulting from the sum of the main lifting height of the main lifting unit and the lifting height of the additional lifting unit is jointly determinable.
Moreover, the control means may be hydraulic control units each comprising a flow distributor or divider and two by-pass valves.
An inventive method for controlling a lifting unit according to the invention may comprise the following steps:
Furthermore, if the lifting difference exceeds a second limiting value, a first lock valve may be closed in addition to opening the by-pass valve.
Moreover, if the lifting difference exceeds a second limiting value, a second lock valve may be closed in addition to opening the by-pass valve.
Furthermore, if the lifting difference exceeds a maximum value the lifting unit may be shut down by closing all lock valves and putting a pumping set out of operation.
Below, the invention will be explained by way of example in more detail with reference to schematic drawings wherein:
FIGS. 1A/1B show a lifting device respectively comprising a main lifting unit 22, 23 in the form of a pantograph lifting platform. The main lifting units 22, 23 comprise a base 110 connected to a floor surface 130, for example a workshop shed. Furthermore, the main lifting units 22, 23 respectively comprise a running rail 202 and a lifting member 14, 15, the lifting members 14, 15, which are shaped in the form of hydraulic cylinders, being used to move the respective running rail 202 substantially perpendicular to the floor surface 130 via the pantograph mechanism. As shown in
A respective additional lifting unit 24, 25, also in the shape of a pantograph lifting platform, may be provided on each running rail 202. The additional lifting units 24, 25 may respectively have a carrier 201 disposed substantially parallel to the running rail 202. The carrier 201 may perform a lifting movement substantially perpendicular to the floor surface 130. The lifting movement of the carrier 201 is accomplished by a respective lifting member 16, 17 in the shape of a hydraulic cylinder. The carrier 201 may be brought into contact with an underbody of a motor vehicle (not shown) in order to lift the motor vehicle to e.g. a total lifting height hg.
In other embodiments of the invention, not shown, the lifting members 14, 15, 16, 17 may be in the shape of pneumatic or hydraulic cylinders, plunger or cylinders, columns and/or spindles. Furthermore, a rack operation is also conceivable.
Furthermore, schematic measuring units are shown which comprise at least one transmitting unit 28 and/or at least one receiving unit 30. A transmitting and receiving unit 28, 30 may respectively be provided for each side of the lifting unit. In this case, the transmitting unit 28 may be attached to the workshop shed floor 130, sending signals in a contact-free manner, for example, in the shape of a laser beam and/or an infrared signal to a receiving unit 30 respectively attached to a bottom side of the carrier 201 of the additional lifting unit 24, 25. Thus, a measuring distance 27 results. However, the measuring units 28, 30 for detecting the lifting height may also be in the form of an ultrasonic sensor or a cable pull. It should be explicitly mentioned here that the arrangements of the transmitting unit 28 and the receiving unit 30 may also be exchanged with each other, that is, the receiving unit 30 may be disposed on the floor surface 130 and on an unmoved part, respectively, and the transmitting unit 28 may be disposed on the carrier 201 and a moved part, respectively.
A control unit 200 (see
The oil flow generated by a hydraulic pump 1 is approximately uniformly distributed to the lifting units 22, 23, 24 and/or 25 via the flow divider 2.
A check valve 3 provides for the fact that in case of a stationary drive motor 4 the hydraulic oil cannot flow back into the tank 6 via the pump 1 and the filter 5. Furthermore, a pressure control valve (PCV) 7 is provided in order to protect the lifting units and the entire hydraulic system from overload. If a difference in the lifting height is determined by the measuring units, one of the two by-pass valves 8, 9 is opened by a control unit 200 and a part of the oil volume flow is directed back into the tank 6. In this case the compensation speed can be adjusted via throttle valves 10, 11. In order to lower the lifting platform the pumping set 41 is switched off and the lowering valve 12 is opened. The lowering speed is regulated via another throttle valve 13. If a difference in the lifting height is detected during the lowering process, the by-pass valves 8, 9 are opened and an additional amount of oil is discharged on the side of the lifting unit having the greater height.
In another suitable embodiment of the invention the hydraulic set (control unit and/or controller) 200 is used to drive the lifting members 14, 15. When the main lifting unit 22, 23 is to be lifted or lowered, both seat valves 18, 19 are opened.
If, on the other hand, the additional lifting units 24, 25 are to be moved, the seat valves 20, 21 are opened and the cylinders 16, 17 are connected to the controller 200. The control valves 8, 9 as well as the flow divider 2 are likewise responsible for the main lifting units 22, 23 and the additional lifting units 24, 25.
The electric measuring units 28, 30 may for example be designed as an ultrasonic measuring unit and/or a cable transducer. To this end, they are arranged such that not only the lifting height of the main lifting unit 22, 23 or additional lifting unit 24, 25 is measured but also the sum of the heights of a main lifting unit 22, 23 with the additional lifting unit 24, 25 attached thereto. In the control unit 200 counting mechanisms for the lifting heights of the main and additional lifting units are separated from each other by assigning the change in the lifting height of the respective lifting unit in accordance with the valve position of the main actuators 18, 19 and the additional actuators 20, 21.
Furthermore, operating members (not shown) are provided for operating the lifting device. For this purpose, an operating member for lifting and another operating member for lowering the respective lifting unit 22, 23, 24, 25 is respectively provided for the main lifting units 22, 23 and for the additional lifting units 24, 25. By operating the respective lifting or lowering operating member of the main lifting unit 22, 23, two substantially parallel main lifting units 22, 23 are simultaneously made to perform a lifting or lowering movement. Likewise, by operating the respective lifting or lowering operating members for the additional lifting unit 24, 25, two substantially parallel additional lifting units 24, 25 are made to perform a lifting or lowering movement. If the control unit 200 for controlling a main lifting unit 22, 23 is activated and an operating member for operating the additional lifting unit 24, 25 is operated, the control unit 200 is switched over to the additional lifting unit 24, 25. An analogue switch-over takes place when as a final step an additional lifting unit 24, 25 was controlled by the control unit 200 and an operating member of the main lifting unit 22, 23 is operated.
The control unit 200 may be connected to an input unit 60 which is shown in
Furthermore, the control unit 200 is connected to a display unit 70 which is capable of indicating data with respect to the target lifting height values of the main lifting height as well as the total lifting height and data of the actual height of the main lifting unit 22, 23 as well as the additional lifting unit 24, 25.
In another embodiment not shown, the main lifting unit 22, 23 as well as the additional lifting unit 24, 25 may respectively be in the form of a column lifting platform or plunger lifting platform and/or consist of a combination of column lifting platforms, plunger lifting platforms and/or pantograph lifting platforms.
The above-mentioned features and exemplarily described embodiments of the present invention may arbitrarily be combined with each other in part or as a whole to form further embodiments adapted to corresponding applications of the invention. As far as such embodiments result from the above-mentioned embodiment examples for a person skilled in the art, they are to be considered as implicitly disclosed by the above embodiment examples.
Number | Date | Country | Kind |
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10 2008 021 149.4 | Apr 2008 | DE | national |