EP4015430A1 - Method for operating an elevator equipped with a positioning system and corresponding devices - Google Patents

Abstract

A method for operating an elevator system (10) and a position determination system (28) configured to carry it out and provided in the elevator system for determining a car position of an elevator car (14) that can be moved in an elevator shaft (12) are described. The method comprises: - Saving a last current car position determined by means of the position determination system (28) at a time before an interruption in the power supply to the elevator system (10) occurs; - Carrying out a calibration run of the elevator car (14) within the elevator shaft (12) after the end of the Power supply interruption, in order to use the position determination system (28) to determine an updated car position at a point in time after the power supply interruption to the elevator system (10), a direction (37) of the calibration journey being defined as a function of the last current car position stored.

Description

The invention relates to a method for operating an elevator installation, which has a position determination system, with the aid of which a car position of an elevator car that can be moved in an elevator shaft can be determined. The invention also relates to a position determination system and an elevator system, which are configured to carry out the corresponding method.

the EP 1412274 B1 describes a position determination system and a method for determining a car position of an elevator car that can be moved in an elevator shaft. The position determination system has a code mark pattern attached parallel to a travel direction next to the elevator car, with n consecutive code marks of the code mark pattern forming a position mark. The code marks form magnetic poles, so that the code mark pattern is made up of a series of magnetic north and south poles. The position marks are uniquely arranged in an n-digit pseudo-random sequence of different position marks, the position marks forming a single-track code mark pattern. A discrete car position is assigned to each of the position markers mentioned via an assignment table.

The position determination system has a detection device arranged on the vehicle cabin, which can detect a complete position mark at once. For this purpose, the detection device has a series of Hall sensors, which scan the code mark pattern without contact and thus detect the position mark. The number and the arrangement of the Hall sensors are selected in such a way that a detection length of a detection area of the detection device extends over at least one position mark length of a position mark in the direction of travel. It is thus possible to record a complete position mark immediately after restarting the position determination system.

The position determination system also has an evaluation unit, which determines a cabin position on the basis of the position mark detected by the detection device. It is thus possible to determine the cabin position immediately after starting the position determination system.

That in the EP 1412274 B1 described position determination system requires a variety of Hall sensors, which is associated with significant material costs and a significant amount of space.

the EP 1634841 A1 and the EP 1637493 A1 also describe position determination systems for determining a car position of an elevator car that can be moved in an elevator shaft, which position markers can completely detect at a point in time.

To reduce technical complexity, material costs and / or space, was in the WO 2019/206644 A1 proposed a simplified position determination system in which the number of built-in Hall sensors was kept low. For example, this position determination system can only have a few, for example only three, such sensors. Accordingly, not all code marks of a position mark can be detected simultaneously with such a position determination system. In order to detect the code marks of the entire position mark, the position determination system is therefore moved with its sensors successively along the code marks as part of a calibration run and these are read out one after the other until the entire position mark has been determined. After the calibration run has been carried out, information about an absolute position of the elevator car within the elevator shaft is therefore available even when using such a simplified position determination system.

However, it was observed that shortcomings can occur when using the simplified position determination system in certain operating situations. In particular, it has been observed that if a power supply to the elevator installation is interrupted, problems can arise when operation is subsequently resumed.

There may therefore be a need for a method for operating an elevator installation that is equipped with a position determination system, which makes it possible to determine a car position with increased reliability in different operating situations. Furthermore, there may be a need for a correspondingly configured position determination system and an elevator system equipped with it.

Such a need may be met by the subject matter of the independent claims. Advantageous embodiments are specified in the dependent claims and the following description and figures.

• Abspeichern einer mittels des Positionsbestimmungssystems ermittelten zuletzt aktuellen Kabinenposition zu einem Zeitpunkt vor einem Eintreten einer Stromversorgungsunterbrechung zu der Aufzuganlage;
• Durchführen einer Kalibrierungsfahrt der Aufzugkabine innerhalb des Aufzugschachts nach Beendigung der Stromversorgungsunterbrechung, um mittels des Positionsbestimmungssystems eine aktualisierte Kabinenposition zu einem Zeitpunkt nach der Stromversorgungsunterbrechung zu der Aufzuganlage zu ermitteln, wobei eine Richtung der Kalibrierungsfahrt in Abhängigkeit von der abgespeicherten zuletzt aktuellen Kabinenposition festgelegt wird.

According to a first aspect of the invention, a method for operating an elevator installation is proposed. In this case, the elevator system has a position determination system for determining a car position of an elevator car that can be moved in an elevator shaft. The method comprises at least the following steps, preferably in the order given:

• Saving a last current car position determined by means of the position determination system at a point in time before an interruption in the power supply to the elevator installation occurs;
• Carrying out a calibration run of the elevator car within the elevator shaft after the end of the power supply interruption in order to use the position determination system to determine an updated car position at a point in time after the power supply interruption to the elevator system, with a direction of the calibration run depending on the saved last current car position being defined.

According to a second aspect of the invention, a position determination system for determining a car position of an elevator car that can be moved in an elevator shaft of an elevator installation is proposed, the position determination system being configured to carry out the method according to an embodiment of the first aspect of the invention independently or in cooperation with a controller of the elevator installation or to control.

According to a third aspect of the invention, an elevator system is proposed that comprises a positioning system according to an embodiment of the second aspect of the invention.

Possible features and advantages of embodiments of the invention can be considered, among other things, and without limiting the invention, as being based on the ideas and insights described below.

As already mentioned in the introduction, position determination systems have been developed which are constructed in a relatively simple and therefore cost-effective manner and with the aid of which a position of an elevator car in an elevator shaft can be determined. With these position determination systems, however, it is necessary for the elevator car, together with a detection device attached to it, to be displaced relative to a plurality of code marks distributed in the elevator shaft, at least at the start of operation, in order to be able to read out these code marks successively. The position determination system can determine the current position of the elevator car within the elevator shaft absolutely and unambiguously only after a corresponding calibration run has been carried out.

It has now been recognized that in the event of a temporary interruption of a power supply within the elevator system, the problem can arise that the position determination system "forgets" the previously known current position of the elevator car. A supplementary energy source, for example in the form of a battery, is typically provided in an elevator system in order to be able to bridge short-term power failures. In the event of longer power failures, however, it can happen that a power supply for the position determination system is ultimately interrupted and data present in the position determination system are thus lost.

After the end of the power supply interruption, the position determination system can in principle resume its operation. However, at the beginning it does not know at which position within the elevator shaft the elevator car is currently located. Therefore, as a rule, provision can be made for a new calibration run to be carried out before starting regular operation of the elevator installation. Since it must also be ensured during the calibration run that the elevator system does not move into an impermissible configuration, For example, by moving the elevator car beyond a permissible travel range, such a calibration travel is usually initiated and/or monitored by a technician. This involves a great deal of effort, since the technician usually has to visit the elevator system on site.

The aim of the approach presented here is to be able to generally avoid such an expense resulting from a temporary power supply interruption.

For this purpose, the position of the elevator car is determined during normal operation of the elevator system using its position determination system continuously or at certain time intervals, for example periodically at time intervals of, for example, less than 20 s or even less than 2 s. This determined position is then saved in each case. When storing in this way, information about a newly determined position may overwrite previously stored information, so that only a small amount of storage space is required. A car position determined immediately before a power interruption occurs is referred to herein as "last current car position". This last current car position thus indicates where the elevator car was located within the elevator shaft shortly before the power supply was interrupted.

After the power supply interruption has ended, a calibration run can then be carried out. The purpose of the calibration drive is to use the position determination system to determine the actual cabin position. This car position is referred to herein as "updated car position".

When this calibration run is carried out, the information about the last current cabin position stored before the power supply was interrupted is taken into account. In particular, the direction in which the calibration drive is carried out is determined as a function of the last current car position that was stored.

This can be achieved that the calibration drive after the Power supply interruption automated as a rule, that can be carried out in particular without initiation and / or special monitoring by a technician.

This is based on the consideration that it is known that the actual position of the elevator car within the elevator shaft can change in principle during a power supply interruption, but that such changes in the car position usually only slightly modify the absolute position of the car within the elevator shaft. In particular, it is known that during a lengthy operational interruption as a result of a power failure, the elevator car can slowly change its position within the elevator shaft, for example due to so-called "creeping" of a drive device driving the elevator car. It is also known that the elevator car can be relocated within the elevator shaft in a targeted manner, for example as part of an evacuation measure. However, it has been observed that such changes in position almost never result in the elevator car being displaced from one end of the elevator shaft to an opposite end of the elevator shaft. Instead, the elevator car is typically only moved up to the next floor, for example during an evacuation measure. Accordingly, the actual car position after the end of the power supply interruption agrees at least roughly with the last current car position before the power supply interruption. The information about the at least roughly correct car position can then be taken into account when carrying out the calibration trip.

In particular, according to one embodiment, the calibration run can be carried out in a direction away from an end of the elevator shaft that is closer to the last current car position than an opposite end of the elevator shaft.

In other words, the last car position determined before the power supply interruption occurred can be analyzed as to whether the elevator car was closer to a lower end or closer to an upper end of the elevator shaft. In the event that the elevator car was last located closer to one of the ends of the elevator shaft, the calibration run should then be carried out in this way become that the elevator car is moved away from this nearer end. In this way, a risk that the elevator car is moved beyond a permissible travel path during the calibration run and, for example, rams a travel path limitation or a buffer provided there, can be minimized.

According to one embodiment, the last current car position can be stored in a memory that is independent of the power supply to the elevator system.

In other words, the car positions determined during normal operation of the elevator installation using the position determination system can be stored in a memory that is independent of the rest of the power supply of the elevator installation. For example, such a memory can have its own power supply. Alternatively, the memory can be located outside the elevator system. For example, the memory can be provided in a monitoring center, with the help of which the elevator system is monitored remotely and to which the last current car positions are transmitted.

This can ensure that despite the
Power supply interruption to the elevator system, the information about the last current car position is retained.

In particular, according to one embodiment, the last current car position can be stored in a non-volatile memory. Such non-volatile memory does not require a power supply to store data. A last current car position stored in it is thus retained regardless of a power supply interruption. For example, a flash memory, an EEPROM or the like can be used as the non-volatile memory.

According to one embodiment, the position determination system can be configured to determine the last current car position and the updated car position in each case by reading out a plurality of code marks distributed along the elevator shaft. The position determination system can also be configured to only read out a limited number of code marks at the same time, which is smaller than a number of code marks required for unambiguousness, which are required to be able to unambiguously determine the car position. In addition, during the Calibration drive a number of code marks used for calibration can be read out in order to redetermine the updated car position after the power supply interruption.

In other words, the position determination system of the elevator installation to be operated according to the method proposed here can be a simply constructed position determination system, as was already roughly described at the outset. This position determination system can have a small number of sensors, in particular Hall sensors, for example, so that only a limited number of code marks can be read out at the same time. This limited number can be less than ten, preferably less than five, for example. For example, only one, two or three sensors can be provided in the position determination system.

However, in order to be able to unequivocally infer a current position of the elevator car from the code marks read out, more than this limited number of code marks must be read out. The number of code marks required for this is referred to herein as the "number of code marks required for uniqueness". It can depend, among other things, on the length of the elevator shaft and/or other conditions and can typically be greater than the limited number of code marks corresponding to the number of sensors in the position determination system, for example greater than ten, preferably greater than 14.

A number of code marks are then read out as part of the calibration drive in order to determine the updated cabin position. This number is referred to herein as the "number of code marks used for calibration" and can be between the limited number of code marks to be read out simultaneously by the positioning system and the number of code marks required for uniqueness, i.e. for example between two and 14, preferably three and ten code marks .

In particular, according to one embodiment, the number of code marks used for the calibration can be smaller than the number of code marks required for uniqueness.

In other words, during the calibration drive using the position determination system, a number of code marks does not necessarily have to be read out, which would be necessary without any prior knowledge in order to be able to clearly determine the current cabin position using the code marks read out. For example, the number of code marks used for calibration can be one, two, three or more code marks less than the number of code marks required for uniqueness.

In many cases, the updated car position can nevertheless be determined exactly and unambiguously with a sufficiently high degree of probability or even certainty, in that the previously stored information about the last current car position before the power supply interruption is taken into account when evaluating the code marks read out. The calibration trip can thus be kept short with regard to the distance covered and/or with regard to the time required for this.

In particular, according to one embodiment, when determining the updated car position, the code marks read out during the calibration trip can be compared with code marks that were read out when determining the last current car position.

In other words, when determining the updated car position, not only can the code marks read out during the calibration run be analyzed, but they can also be compared with the code marks that correspond to the previously determined last current car position.

For this purpose, the code marks corresponding to the last current car position can be stored together with the last current car position or as information representing this last current car position. Alternatively, information about the various code marks provided along the elevator shaft can be present in the position determination system, for example in the form of a table, so that the code marks associated with this car position can be inferred from the previously stored last current car position. By comparing the code marks read out during the calibration drive with the code marks associated with the last current car position, additional information can be taken into account when determining the updated car position.

If both sets of code marks are identical, for example, a probability that the elevator car has not moved during the power supply interruption can be assumed to be high. In the event that both sets of code marks have differences, it can be assumed that the elevator car has been moved in the meantime.

The greater the number of code marks read out during the calibration journey and/or the number of code marks of the last current cabin position compared with them, the higher the probability that the updated cabin position determined is correct, even if the number of code marks during the calibration journey code marks read out should be smaller than the number of code marks required for uniqueness.

• ein parallel zu einer Verfahrrichtung neben der Aufzugskabine angebrachtes Codeband mit einem aus einzelnen Codemarken aufgebauten Codemarkenmuster,
• eine an der Aufzugkabine angebrachte Erfassungsvorrichtung zum Erfassen von Codemarken des Codemarkenmusters des Codebands und
• eine Auswerteeinheit zur Bestimmung der Kabinenposition auf Basis der von der Erfassungsvorrichtung erfassten Codemarken,

wobei n aufeinanderfolgende Codemarken des Codemarkenmusters eine Positionsmarke bilden, die Positionsmarken in einer n-stelligen Pseudozufallsfolge verschiedener Positionsmarken eindeutig angeordnet sind, die Positionsmarken ein einspuriges Codemarkenmuster bilden und jeder Positionsmarke eine diskrete Kabinenposition zugeordnet ist, und
wobei ein Erfassungsbereich der Erfassungsvorrichtung eine Erfassungs-Länge in Verfahrrichtung aufweist, welche kleiner ist als eine Positionsmarken-Länge einer Positionsmarke in Verfahrrichtung.According to one embodiment, the position determination system used within the scope of the method proposed here can have at least the following components:

• a code tape attached parallel to a direction of travel next to the elevator car with a code mark pattern made up of individual code marks,
• a detection device mounted on the elevator car for detecting code marks of the code mark pattern of the code tape and
• an evaluation unit for determining the cabin position on the basis of the code marks detected by the detection device,

where n consecutive code marks of the code mark pattern form a position mark, the position marks are uniquely arranged in an n-digit pseudo-random sequence of different position marks, the position marks form a single-track code mark pattern and each position mark is assigned a discrete car position, and
wherein a detection range of the detection device has a detection length in Has direction of travel, which is smaller than a position mark length of a position mark in the direction of travel.

In other words, the position determination system can be of the type described in the earlier patent application cited at the outset WO 2019/206644 A1 has been described in detail. The content of this earlier patent application is to be incorporated herein in its entirety by reference. Advantageous configurations of the position determination system described in the earlier patent application can also be used in the same or a similar way for the position determination system described herein and the method using it for operating the elevator installation.

A positioning system that is similar in many features is used by the Company ELGO ELECTRONIC GmbH & Co. KG (Germany) as a mini manhole information system called "LIMAX1M" (see also: https://www.elgo.de/produkte/messsysteme/schachtinformationssysteme/limaxlm/; as of November 2020 ).

According to one embodiment, the calibration run can be shorter than a distance between two adjacent floors along the elevator shaft, in particular shorter than 1 m or even shorter than 0.3 m.

In other words, it may be sufficient to only carry out the calibration run over a very short distance. A length of this distance can result from a distance between adjacent code marks and a number of code marks that is required in order to be able to deduce a correct updated car position with sufficient probability. A distance between adjacent code marks is typically in the range of a few millimeters, for example between 5 mm and 10 mm. Assuming that between 5 and 25 code marks have to be read in order to be able to deduce the updated car position, a calibration run over a distance of 25 cm or less can be considered sufficient.

According to one embodiment, after the power supply interruption to the Elevator system in a period of time until the updated cabin position has been determined, safety-critical functions during operation of the elevator system are made available at most to a limited extent.

In other words, the fact that there is no reliable information about the actual position of the car until the updated car position is determined after the power supply interruption can be taken into account to the effect that at least one or some safety-critical functions during operation of the elevator system are not permitted or only permitted to a limited extent will. As a result, safety during operation of the elevator installation can be further improved.

For example, until the updated car position has been reliably determined, bridging of door contacts on elevator doors cannot be permitted, at least temporarily. Such bridging of door contacts, which is also referred to as "door overbridging", can be used during normal operation to be able to open the door of the elevator car and/or on a floor, although the elevator car is still moving within the elevator shaft and opening the door for safety reasons would therefore generally not be permitted. As a result, the doors can already be opened, for example, just before the elevator car actually reaches a destination floor. Alternatively, despite the car door being open, the elevator car can be moved slightly, for example in order to level out changes in the car's position, which can be caused by varying loads inside the car (so-called "re-levelling").

Alternatively or additionally, a function often referred to as ETSL can be suspended or restricted until the updated car position has been reliably determined. ETSL is the abbreviation for the English term "Emergency Terminal Speed Limiting". Buffers provided at the end of the elevator shaft could be buffered. It is assumed here that a current position of the elevator car is taken into account in such a way that a travel movement of the elevator car is automatically slowed down when the elevator car approaches the buffer approaches. However, as long as this current cabin position is not reliably known, the mentioned function can remain suspended or restricted. The elevator car is advantageously only displaced relatively slowly during the calibration run anyway, for example at less than 1 m/s or even less than 0.5 m/s, so that its speed remains below a limit to be buffered by the buffer.

In order for the position determination system to be able to communicate appropriately with other components of the elevator system as part of the method described herein, in order to implement the functionalities provided for the method described, an interface can be provided in the position determination system and the position determination system can be configured to respond to a power supply interruption to the elevator system to transmit an instruction to the controller of the elevator system via the interface in order to cause it to relocate the elevator car to carry out the calibration journey.

In this case, data or signals can be exchanged via the interface, for example with an elevator controller and/or a monitoring center used to monitor the elevator installation. Based on such data or signals, a drive device of the elevator system can then, for example, control a corresponding shifting of the elevator car so that the components of the position determination system attached to the elevator car can read corresponding code marks and the updated car position can then be determined.

It is pointed out that some of the possible features and advantages of the invention are described herein with reference to different embodiments of a method for operating an elevator installation on the one hand and a position determination system that can be used for this purpose or an elevator installation equipped therewith on the other hand. A person skilled in the art recognizes that the features can be combined, adapted or exchanged in a suitable manner in order to arrive at further embodiments of the invention.

Embodiments of the invention are described below with reference to the accompanying drawing, neither the drawing nor the description being to be construed as limiting the invention.

1 shows a schematic representation of an elevator installation with a position determination system for determining a car position of an elevator car that can be moved in an elevator shaft according to an embodiment of the present invention.

The figure is merely schematic and not true to scale. The same reference symbols denote the same features or features that have the same effect

1 1 shows an elevator system 10 with an elevator shaft 12 aligned in the vertical direction. An elevator car 14 is arranged inside the elevator shaft 12 and is connected in a known manner to a counterweight 18 via a suspension element 16 in the form of a flexible belt or cable. Starting from the elevator car 14, the suspension element 16 runs over a drive pulley 20, which can be driven by a drive machine (not shown). The elevator car 14 can be moved up and down in the elevator shaft 12 between different floors 7 , 8 , 9 by means of the drive machine and the suspension element 16 . The elevator car 14 can thus be moved in the elevator shaft 12 in or counter to a direction of travel 22 which runs upwards in the vertical direction.

A guide rail 26 running in the direction of travel 22 is fixed to a shaft wall 24 of the elevator shaft 12 . When the elevator car 14 is moved, it is guided along the guide rail 26 via guide shoes (not shown).

A code tape 27 in the form of a magnetic tape is arranged on the guide rail 26 . The code tape 27 serves as a carrier for a single-track combined code mark pattern from a plurality of code marks 29 which form position marks 25, the code mark pattern representing the numerical code of absolute positions of the elevator car 14 in the shaft 12 based on a zero point. The code tape could also be arranged independently of a guide rail in the elevator shaft.

The code tape can also be used as a tape with a hole pattern, holes of the hole pattern forming code marks. The code strip can in particular be designed as a metal strip with a punched hole pattern.

Parts of a position determination system 28 for determining a car position of the elevator car 14 are arranged on or on the elevator car 14 . The position determination system 28 has an evaluation unit 30 and a detection device 32 which are arranged on or on the elevator car 14 . The position determination system 28 also includes the code tape 27.

The detection device 32 is arranged on the elevator car in such a way that it can detect position marks 25 formed by the code tape 27 . The evaluation unit 30 and thus the position determination system 28 can thus determine the car position of the elevator car 14 .

Details on possible configurations of the elevator system 10 and its position determination system 28 are in FIG WO 2019/206644 A1 specified.

Independent of the position determination system 28, the elevator installation 10 can have further position determination means 36, with the aid of which information about the current position of the elevator car 14 can be determined and which can communicate directly with an elevator controller 35, for example.

Furthermore, the position determination system 28 can have an interface 41 via which it can send data and/or signals to other components, in particular to the elevator control 35 and/or to an external monitoring center 33 connected to a data cloud 31 (cloud).

During operation of the elevator system 10, the current position of the elevator car 14 is determined using the position determination system 28 continuously or at short time intervals. The last current cabin position determined is then stored in a memory 40 in each case. The memory 40 can be arranged, for example, in the position determination system 28, in particular in its evaluation unit 30. Alternatively, the memory 40 can be located, for example, in the remote

Monitoring center 33 are located and the information about the last current cabin position is sent from the position determination system 28 to this memory 40, for example via the data cloud 31. The memory 40 can be independent of a power supply for the rest of the elevator installation 10 . In particular, the memory 40 can be a non-volatile memory.

If a temporary power supply interruption occurs in the elevator system 10, the information about the last current car position can then be used after the end of the power supply interruption in order to be able to carry out a necessary calibration run of the elevator car in a suitable manner.

In particular, this information is used to suitably define a direction 37 in which the calibration run is to be carried out. For example, the information about the last current car position is analyzed to determine whether the elevator car 14 was closer to a lower end 38 or closer to an upper end 39 of the elevator shaft 12 before the power failure. Depending on which of the opposite ends 38, 39 the last current car position is closer to, the calibration run is then preferably initiated in a direction 37 away from this end 38, 39 of the elevator shaft 12 that is closer. For this purpose, the position determination system 28 can, for example, send a suitable control signal to the elevator control 35 via an interface 41 .

In this way, a risk that the elevator car 14 is moved beyond the end of a permissible travel path during the calibration journey, for example, can be minimized.

In order to make the calibration run as short as possible or to be able to carry it out quickly, the code marks 29 read out during the calibration run can be compared with code marks 29 as they were previously read out when determining the last current car position. As a result, additional information can be derived which can be used to be able to determine the updated car position with sufficient certainty using a number of code marks 29 which is less than a necessary number of code marks 29, which are required without such additional knowledge in order to be able to clearly determine the cabin position.

Finally, it should be noted that terms such as "comprising," "comprising," etc. do not exclude other elements or steps, and terms such as "a" or "an" do not exclude a plurality. Furthermore, it should be pointed out that features or steps that have been described with reference to one of the above exemplary embodiments can also be used in combination with other features or steps of other exemplary embodiments described above. Any reference signs in the claims should not be construed as limiting.

Claims (15)

Method for operating an elevator system,
wherein the elevator system (10) has a position determination system (28) for determining a car position of an elevator car (14) that can be moved in an elevator shaft (12),
the method comprising: - Storage of a means of the position determination system (28) determined last current car position at a time before an occurrence of an interruption in the power supply to the elevator system (10); - Carrying out a calibration run of the elevator car (14) within the elevator shaft (12) after the end of the power supply interruption in order to use the position determination system (28) to determine an updated car position at a point in time after the power supply interruption to the elevator system (10), with a direction (37 ) of the calibration run depending on the saved last current cabin position. Method according to claim 1,
wherein the calibration run is performed in a direction (37) away from an end (38, 39) of the elevator shaft (12) which is closer to the last current car position than an opposite end (39, 38) of the elevator shaft (12). Method according to one of the preceding claims,
the last current car position being stored in a memory (40) independent of the power supply to the elevator installation (10). Method according to one of the preceding claims,
the last current cabin position being stored in a non-volatile memory (40). Method according to one of the preceding claims,
wherein the position determination system (28) is configured to determine the last current car position and the updated car position in each case by reading out a plurality of code marks (29) distributed along the elevator shaft (12), wherein the position determination system (28) is further configured to only read out a limited number of code marks (29) at the same time, which is smaller than a number of code marks (29) required for unambiguousness, which are needed to be able to unambiguously determine the cabin position , and
a number of code marks (29) used for the calibration being read out during the calibration run in order to redetermine the updated cabin position after the power supply interruption. Method according to claim 5,
the number of code marks (29) used for the calibration being smaller than the number of code marks (29) required for clarity. Method according to one of claims 5 and 6,
wherein when the updated car position is determined, the code marks (29) read out during the calibration trip are compared with code marks (29) that were read out when the last current car position was determined. Method according to one of claims 5 to 7,
wherein the positioning system (28) comprises: - a code tape (27) attached parallel to a travel direction (22) next to the elevator car (14) with a code mark pattern made up of individual code marks (29), - A detection device (32) attached to the elevator car (14) for detecting code marks (29) of the code mark pattern of the code tape (27) and - an evaluation unit (30) for determining the cabin position on the basis of the code marks (29) detected by the detection device (32), where n consecutive code marks (29) of the code mark pattern form a position mark (25), the position marks (25) are uniquely arranged in an n-digit pseudo-random sequence of different position marks (25), the position marks (25) form a single-track code mark pattern and each position mark (25 ) is assigned a discrete car position, and
wherein a detection range of the detection device (32) has a detection length in the direction of travel which is smaller than a position mark length of a Position mark (25) in the direction of travel (22). Method according to one of the preceding claims,
wherein the calibration run is shorter than a distance between two adjacent floors (7, 8, 9) along the elevator shaft (12), in particular shorter than Im. Method according to one of the preceding claims,
wherein, after the power supply to the elevator system (10) has been interrupted, safety-critical functions during operation of the elevator system (10) are made available at best to a limited extent for a period of time until the updated car position has been determined. Position determination system for determining a car position of an elevator car (14) of an elevator system (10) that can be moved in an elevator shaft (12), the position determination system (28) being configured to carry out the method according to one of the preceding claims independently or in cooperation with an elevator control (35) carry out or control the elevator system (10). Position determination system according to claim 11,
wherein the position determination system (28) has an interface (41) and is configured to transmit an instruction to the elevator controller (35) of the elevator system (10) via the interface (41) after a power supply interruption to the elevator system (10) in order to to cause the elevator car (14) to be moved to carry out the calibration run. Position determination system according to one of claims 11 and 12,
wherein the position determination system (28) is configured to determine the last current and the updated car position in each case by reading out a plurality of code marks (29) distributed along the elevator shaft (12),
wherein the position determination system (28) is further configured to only read out a limited number of code marks (29) at the same time, which is smaller than a number of code marks (29) required for unambiguousness, which are required to be able to determine the cabin position unambiguously , and
wherein during the calibration run a number of used for calibration Code marks (29) is read to determine the updated car position after the power supply interruption again. Position determination system according to claim 13,
wherein the positioning system (28) comprises: - a code tape (27) attached parallel to a travel direction (22) next to the elevator car (14) with a code mark pattern made up of individual code marks (29), - A detection device (32) attached to the elevator car (14) for detecting code marks (29) of the code mark pattern of the code tape (27) and - an evaluation unit (30) for determining the cabin position on the basis of the code marks (29) detected by the detection device (32), where n consecutive code marks (29) of the code mark pattern form a position mark (25), the position marks (25) are uniquely arranged in an n-digit pseudo-random sequence of different position marks (25), the position marks (25) form a single-track code mark pattern and each position mark (25 ) is assigned a discrete car position, and
wherein a detection range of the detection device (32) has a detection length in the direction of travel which is smaller than a position mark length of a position mark (25) in the direction of travel (22). Elevator installation with position determination system (28) according to one of Claims 11 to 14.

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