The invention relates to an elevator device for transporting persons and/or objects within an elevator shaft of a building or the like, a building including the elevator device, and a position determining device.
The prior art discloses elevators or elevator systems for buildings in which the position of the elevator cabin of the elevator car is detected on the basis of a magnetic strip. This magnetic strip is in this case often fastened to the running framework or to a guiding rail of the running framework. This running framework serves for guiding or mounting the elevator car, i.e. the running framework provides the elevator car with a guide in which the elevator car is moved or can be moved.
The present invention addresses the problem of providing an elevator device, a position determining device and a building with which improved positional determination of the elevator car is made possible.
Accordingly, an elevator device according to the present invention is distinguished by the marking unit being formed as a carrier of a barcode, in particular a 2-D code, and the detection unit being formed as an image sensor, in particular as a camera.
The elevator device according to the invention serves for transporting persons and/or objects within an elevator shaft of a three-dimensional formation or the like. Such a three-dimensional formation may be, for example, a building. For the purposes of the invention, a building should be understood as meaning any type of structure, for example, a house, a high-rise block, a tower, a hall, a stadium with a grandstand, a store, a transporting or loading station or the like. It may, however, also be some other three-dimensional formation comprising at least two levels. In principle, such a three-dimensional formation may also be, for example, a vehicle that has a building-like superstructure, for example a ship. Also conceivable, for example, are elevator devices in mobile transporting or lifting devices. Such an elevator device has an elevator car in which the persons and/or objects to be transported can be accommodated. The elevator car is moved within a running framework for mounting or guiding the elevator car. The running framework is in this case installed within an elevator shaft.
In order to determine the position of the elevator car within the elevator shaft or with respect to the running framework, there is a position determining device. This comprises at least one marking unit for marking the position, also a detection unit for detecting or reading out the marking unit and an evaluation unit for evaluating the measured values of the detection unit. This evaluation unit may be formed, for example, as an electronic unit which reads out output measured values of the detection unit and uses them for determining on this basis a position indication as to the position of the elevator car with respect to the running framework or the position within the elevator shaft.
The measure that the marking unit is formed as a carrier of a barcode, in particular a 2-D code, and the detection unit is formed as an image sensor, in particular as a camera, allows the positional determination to be improved. On the one hand, the use of a barcode or a 2-D code makes it possible to perform a simple, low-cost marking. For example, such a marking can be printed on in a simple manner with little cost. Such a marking can also be read out with standard scanners or other image sensors intended for this. Moreover, particularly error-free reading out is thereby made possible. Since the corresponding barcodes or 2-D codes can be very sharply depicted and, what is more, can also be placed very accurately with respect to the running framework or the elevator shaft, and very precise image-sensory detection is possible, the position can also be determined very precisely.
Since such barcodes or 2-D codes have a correspondingly high black-and-white contrast, these markings are often less susceptible to contaminants, such as for example due to dust. Conversely, it is also possible furthermore to determine the contrast of the detected marking units optically by means of the image sensor and, if appropriate, to output a corresponding error or warning signal or a maintenance signal, which indicates that the corresponding marking units must be cleaned or renewed. Such a maintenance or error signal may, for example, be output by the evaluation unit, in which the contrast may also be determined. Moreover, a barcode or 2-D code can advantageously be read out contactlessly and, what is more, is also virtually wear-free.
Correspondingly accurate detection is made possible by image sensors which have a corresponding optical system, such as for example telecentric lenses. Furthermore, it is made possible to provide image sensors that are as compact and small as possible.
This simple and compact configuration makes it possible that only low costs are incurred for the positional determination. Moreover, such positional determination makes low power consumption possible, since often only low power is usually required for the corresponding electronics.
In the case of a preferred embodiment of the invention, the marking unit is also formed as a strip; this measure makes continuous marking of the position along the run of the elevator car possible. Each individual marking can be separated from the next marking by a corresponding symbol, for example a separating strip, so that a fine incrementation is also made possible.
In the case of a preferred embodiment of the invention, the marking unit is attached to the running framework, in particular to a guiding rail of the running framework. In the case of such a configuration, it is made possible, for example, that the marking is not concealed by struts or the like when the elevator car travels past. Moreover, it can in this way be achieved that a specific, exactly defined distance between the sensor/image sensor and the marking unit is always maintained. On the one hand, this allows the accuracy of the measurement to be increased and, on the other hand, this measure also makes simplified installation and maintenance possible. In particular, the positional determination does not have to make allowance for any influence with regard to a measurement that could be caused by a change in the distance between the marking strips and the sensor. A small distance between the marking strips and the sensor usually makes it possible for the positional determination to be performed precisely.
After they have been constructed, building structures may also “settle” over time, i.e., for example, walls may change their position and be displaced slightly. Such changes are known in structural engineering and structural physics and are caused, for example, by effects of ageing and loads. Changes due to seismic activities or other changes of the subsoil (for instance caused by subsidence, groundwater, etc.) are also conceivable. However, these displacements are not always linear or uniform. If such a displacement occurs, this may mean that the building is displaced in a way that is different than, for example, the running framework in which the elevator car is guided. A further advantage of attaching the marking unit to the running framework may consequently be that of making it possible for the position of the marking unit to be at least partially isolated from displacements of the building. If, therefore, a corresponding marking unit is fastened directly to the building, for example to a wall of the building, it may change its relative position with respect to detection by an image sensor of an elevator car that can travel in the running framework. If no allowance were made for this effect, this could lead to the positional determination being less accurate after a certain time in which the building or individual walls is/are displaced than when the elevator was installed; correspondingly, the shaft opening could then possibly no longer be approached precisely by the elevator cabin.
In principle, however, the marking unit may also be attached to the elevator shaft or to some other part, for example a wall of the building.
Furthermore, in the case of a development of the invention, at least a first and a second marking unit are provided. This may be accompanied by several advantages: Firstly, a second marking unit may be used as a reference marking for adjusting the accuracy of the first marking unit. For example, the evaluation unit may perform such an adjustment, if appropriate automatically in specific time intervals. This allows the elevator device to establish whether a change has taken place over time with respect to the relative position between the first marking unit and the second marking unit. This may be used for maintenance purposes but also in principle for building safety. Moreover, this allows a calibration of the position determining device to be performed, so that even more precise positional determination is made possible. Such a calibration may be performed in the evaluation unit. The second marking unit may, for example, be attached in the vicinity of the shaft opening, for example on every floor.
A second marking unit may also be used, however, for transmitting further information. For example, the second marking unit may be used for marking a specific zone along the run within the elevator shaft.
Moreover, the evaluation unit may in turn be designed for determining whether or not the elevator car is located within this zone. Such a zone may be, for example, the area around a shaft opening in which it is possible for persons located in the elevator car to exit. Typically there is a shaft opening on every floor, if appropriate even two shaft openings, if for example exiting on opposite sides is possible.
Depending on the type of elevator, either the elevator car has a door or exit hatch or, conceivably, the elevator shaft itself has a corresponding door or exit hatch. Accordingly, in the case of a development of the invention, there may be an unlocking device for unlocking a door or an exit hatch of the elevator car, which device can be controlled by means of an evaluation device. The purpose of such an unlocking device is to make emergency exiting possible if there is an elevator defect, but only when the elevator car is in the area of a shaft opening. It is likewise conceivable for the unlocking device to unlock the door of a shaft opening of the elevator shaft, that is to say a door that is not attached directly to the elevator car. For the purposes of the invention, control means closed-loop and/or open-loop control. For example, depending on whether the elevator car is within the zone, the locking device can or cannot be activated.
In the case of a configurational variant, the detection unit may be arranged on top of and/or underneath the elevator car. It is also conceivable for the detection unit to be attached to the elevator car at some other position. This means that the marking unit is fixedly attached, for example to the running rail or to the building, while the elevator car, which can perform a movement in relation to this marking unit, has the corresponding detection unit, which can, depending on its position with respect to the marking unit, then provide corresponding positional indications on the basis of the evaluation device. However, in principle it is conceivable, for example, for the detection unit also to be attached laterally to the elevator car. Allowance for the position of the detection unit in relation to the elevator car should generally be made, inter alia, in the evaluation of the position of the elevator car by the evaluation device, i.e. the latter must be accordingly configured or preprogrammed.
Accordingly, a building according to the invention with at least two floors is distinguished by an elevator device as claimed in one of the aforementioned claims being provided.
In the case of a preferred embodiment, the second marking unit is attached to the building. This advantageously has the effect, in particular, that a relationship between the running framework or the rail of the running framework and the building is made possible. As already discussed, a non-uniform change in the position of the building in relation to the running framework may occur over time due to ageing, loads, etc. The measure of attaching the second marking unit to the building allows this relative position between the building and the running framework to be newly determined at any time, even when there is a non-uniform change, and renewed calibration to be performed. In principle, it is also conceivable for a corresponding warning function to be activated, for example by the evaluation unit, if this change in position is too great. This second marking unit may, for example, also carry floor information and position information. For example, it may include the number of the individual floor in a coded form.
The position information may be represented in various ways: one is the possibility of point information, which can be used in principle for calibration of the code strip, but also for the calculation of a position, for example of the zone in which unlocking is intended to take place. Furthermore, area information may be coded, for example making it possible for the unlocking zone to be detected directly. Such an area may be defined by a beginning and an end, for example in the case of an unlocking zone an area of approximately 20 cm below a shaft opening to 20 cm above a shaft opening. It is conceivable in principle, for example, for the beginning and the end of an unlocking zone to be detected directly on the basis of a coding on the marking unit.
It is also possible, furthermore, to transmit length information, which can be used for calibration of the code strip but can also lead to increased accuracy if the vernier principle is used. Accordingly, both indirect and direct detection of the unlocking zone are conceivable in principle. Finally, the coding may likewise include floor information. In principle, image sensors may be used for reading out the first and second marking units. The marking units may likewise be used for defining a stopping point of the elevator car. In principle, it is possible to dispense with the floor information if a position can be assigned by the memory of the evaluation unit to the code read out from the marking unit. The corresponding information or assignment table must then be correspondingly stored in advance, for example in the memory of the evaluation unit. The floor information may also be obtained by detecting read-out stopping point information and also reading markings from an extreme position in the course of a learning phase during running. This measure makes good technical feasibility and low-cost implementation possible.
It is conceivable to arrange the second marking unit in such a way that the zone marked by it forms an area around at least one of the shaft openings of the elevator shaft. This zone may serve, for example, as an unlocking zone, i.e. emergency unlocking may take place in this area if the elevator remains at a standstill, for example due to a technical defect or some other unforeseen event. With the aid of the emergency unlocking, the doors can then be brought out of the elevator car through a shaft opening in an area that is safe for the persons or the objects being transported. This measure also allows the safety of the elevator device to be increased.
An exemplary embodiment of the present invention is explained in more detail below, specifying further advantages and further details, and is represented in the drawings.
This exemplary embodiment is a preferred configurational variant.
The camera 4, as an image sensor, is designed in principle for detecting and reading out both the first and the second marking unit. Persons can enter the elevator car 3 through a shaft opening 8 when said car is at the corresponding height, to be more precise at the corresponding position level with the shaft opening 8. The persons can be transported in the elevator car 3 in a vertical direction. The elevator car 3 is in turn mounted and guided by the running framework 2. Furthermore, the elevator car 3 comprises doors, which open and close automatically when the elevator car has reached a corresponding position, for example level with the shaft opening 8.
During the running of the elevator car 3 in the vertical direction, the camera 4 receives corresponding images of the first measuring unit. This image information received from the first measuring unit is processed in the evaluation unit (not represented) and finally results in a positional indication of the elevator car 3 within the running framework 2. Both the second marking unit and the first marking unit contain a barcode or 2-D code to be read out. The image area that the camera 4 detects also makes it possible, however, for the second marking unit to be read out, provided that it can be detected by the camera 4, which in turn depends on the position of the elevator car 3. As represented in
The first marking unit is formed as a strip which carries the barcode; whereas the second marking unit is formed as a 2-D code, the marking unit being formed by a marking piece. In particular, these marking units may be formed by an adhesive strip which carries the corresponding marking or the corresponding barcode or 2-D code.
Number | Date | Country | Kind |
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11 005 240.4 | Jun 2011 | EP | regional |
This application claims the benefit under 35 USC §119(a)-(d) of European Application No. 11 005 240.4 filed Jun. 28, 2011, and claims the benefit under 35 U.S.C. §119(e) of U.S. Provisional Application 61/502,002, filed Jun. 28, 2011, the entireties of which are incorporated herein by reference.
Number | Date | Country | |
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61502002 | Jun 2011 | US |