EP0722903A1 - Method and apparatus for generating shaft information of an elevator shaft - Google Patents

Abstract

The method provides information on an elevator hoistway (1) to control an elevator. An elevator car (6) is provided to be guided in the hoistway. A readable code (3) is arranged in the hoistway. The code is read as an image. At least one pattern in the image of the code is detected. The detected pattern is compared to a reference pattern. Hoistway information is generated from the detected pattern to control the elevator. The appts. includes at least one sensor (10) to read the code. It also includes at least one device to detect the pattern. At least one computing unit evaluates the hoistway information contained in the pattern. Preferably the pattern detected includes at least one light region and one dark region. A pattern repetition distance is then derived from the spacing between the middle of dark regions. The position of the elevator car (6) is read from the repetition distance.

Description

The invention relates to a method and a device for generating shaft information for an elevator shaft, which serves to control the elevator, with an elevator car which can be moved in the elevator shaft and a readable code arranged in the elevator shaft.

From US Pat. No. 4,433,756 an elevator with an elevator shaft is known, in which a coded tape is arranged above the shaft height. The coding consists of openings in the band arranged in two tracks. A light transmitter and an optoelectronic receiver are arranged on an elevator car that can be moved in the elevator shaft. The coded band runs between the light transmitter and the receiver, so that the light rays from the light transmitter either reach the optoelectronic receiver through the openings in the band or are interrupted by the band. When the elevator car is moved, binary-coded information about the position of the elevator car is created.

A disadvantage of the known device is that the length of the elevator shaft and thus the coded tape result in inaccurate car positions. Another disadvantage is the great effort involved in fastening the band in the elevator shaft. In order to avoid misinformation, the belt must be supported precisely over the entire shaft height. In addition, inaccuracies in the guidance of the elevator car can have a negative impact on the reliability of the shaft information. Another disadvantage is that the coded tape protrudes from the shaft wall and into the Chimney protrudes. The shaft cross section must accordingly be dimensioned larger. Another disadvantage with regard to the proof of security is that it cannot be distinguished whether a light transmitter or receiver is defective or whether the light beam is interrupted by the coded tape. The error case can therefore not be distinguished from a normal function.

The invention seeks to remedy this. The invention, as characterized in the claims, achieves the object of avoiding the disadvantages of the known device and of creating a device in which the reliability of the shaft information generated is improved.

The advantage achieved by the invention can essentially be seen in the fact that the safety of the elevator can be guaranteed with the improved reliability of the shaft information. Incorrect shaft information triggered by damaged or defective parts is recognized with the device according to the invention and does not lead to incorrect results. For example, the bridging of door contacts is not triggered when the elevator car moves into a stop if the shaft information required for this is incorrect. Another advantage can be seen in the fact that several functions, for example position monitoring, speed monitoring, door circuit bridging and self-diagnosis, can be carried out with the same device and shaft information. This fulfills the requirement for intrinsic safety.

Fig. 1

ein Diagramm der Kabinenposition in Funktion der Kabinengeschwindigkeit,

Fig. 2

eine erfindungsgemässe Einrichtung zur Erzeugung von Schachtinformation,

Fig. 3

eine Einrichtung zur Auswertung der Schachtinformation,

Fig. 4

einen Ausschnitt eines erfassten Bildes eines Codes,

Fig. 5

ein Flussdiagramm eines Algorithmus zur Steuerung der Auswertung der Schachtinformation und zur zyklischen Selbstüberwachung und

Fig. 6

eine schematische Darstellung zur Aufteilung eines lange dauernden Hardwaretests.

The invention is explained in more detail below with the aid of drawings which illustrate only one embodiment. Show it:

Fig. 1

a diagram of the cabin position as a function of the cabin speed,

Fig. 2

a device according to the invention for generating shaft information,

Fig. 3

a device for evaluating the shaft information,

Fig. 4

a section of a captured image of a code,

Fig. 5

a flowchart of an algorithm for controlling the evaluation of the shaft information and for cyclical self-monitoring and

Fig. 6

a schematic representation of the division of a long-term hardware test.

The invention is explained in more detail below with the aid of an exemplary embodiment for bridging door contacts on the basis of shaft information. When the elevator car drives into the stop, the floor and cabin doors are opened prematurely to save time. The door contacts in the safety circuit of the elevator control system must therefore be bridged by a safety device that is dependent on the shaft information. The same applies to the adjustment of the elevator car, which is lowered by rope stretching, with the doors open.

The areas in which the bridging of the door contacts when entering and adjusting the elevator car is permitted and must be monitored by the inventive safety device can be seen from the diagram in FIG. 1. On the vertical axis of the diagram is the position + P of the elevator car above a stop and the position -P of the elevator car below the Stop shown. In position P ₀ the threshold of the elevator car is flush with the stop. The speed is marked v on the horizontal axis. The position and the speed at which the door contacts can be bridged when retracting is designated + P _E and -P _E or v _E. The position and the speed at which readjustment with bridged door contacts is permitted is denoted by + P _N and -P _N or v _N.

FIG. 2 shows an elevator shaft 1 in the area of a stop with a reflector 2 on which a code 3, for example a 2-zone code, a one- or two-dimensional bar code or a point code, is arranged. In the present exemplary embodiment, a 2-zone code 3 is used. The code 3 is arranged in a first track 4 and a second track 5. In the present example, both tracks 4, 5 are identical in pattern, but they can also be different. The level of the stop is shown with the broken line H ₀ , to which the code 3 is symmetrical. A drive-in area B _E , in which the door contacts can be bridged, is half above and below the level line H ₀ . A readjustment area B _N , in which, with bridged door contacts, readjustment of an elevator car 6 which lowers due to rope expansion when the doors are open, is half above and below the level line H ₀ . The code 3 of the first track 4 and the second track 5 is recorded and evaluated by a 2-channel evaluation device 7 arranged on the elevator car 6, both channels being identical. A first transmitter 8 of the evaluation device 7 illuminates the first track 4 of the reflector 2, a second transmitter 9 of the evaluation device 7 illuminates the second track 5 of the reflector 2. The illuminated area of the first track 4 is on a first CCD sensor 10 of the evaluation unit 7 mapped, the illuminated surface of the second track 5 is mapped on a second CCD sensor 11 of the evaluation unit 7. The optics 12.1 of the transmitter 8 shown in FIG. 3 and the optics 12.2 of the CCD sensor 10 are matched to one another in such a way that the illuminated surface of the reflector 2 is sharply imaged on the CCD sensor in a certain distance range, for example 10 to 30 mm . The same applies to the optics of the second transmitter 9 and the second CCD sensor 11.

FIG. 3 shows a block diagram of the evaluation device 7 shown in FIG. 2 with a first channel 12, a comparator 14 and a second channel 15. The second channel 15 has the same structure as the first channel 13 and is therefore not shown. The first channel 13 consists of the first transmitter 8 with the optics 12.1, the CCD sensor 10 with the optics 12.2, a pattern recognition logic MER, an interface INF, a computer CPU, which via a bus system BUS with a program and parameter memory ROM and is connected to a data memory RAM and to the pattern recognition logic MER and the interface INF and from a relay logic REL to which a relay 16 is connected. If the conditions for retracting or adjusting are met, the relay 16 bridges door contacts 17 of a safety circuit 18. The results of the two channels 13, 15 are compared in the comparator 14 and errors are output in the event of unauthorized deviations. The comparator 14 consists of a position comparator POC, a speed comparator SPC and an error collector FES. A first release signal ENE of the elevator control allows the doors to be opened when the elevator car is retracted and a second release signal ENN of the elevator control allows the elevator car 6 to be readjusted when the doors are open. The enable signals ENE, ENN can also be generated by the evaluation device 7 itself, since the necessary information is available is. When entering the insertion zone B _E, the first enable signal NE is generated. When entering the adjustment range B _N , the second enable signal ENN is generated. When leaving these areas, the enable signals ENE, ENN are reset.

A position signal output by the interface INF is designated POS and a speed signal output by the interface INF is designated SPE. In the event of unauthorized deviations in the position comparator POC, a first error signal FEP and in the event of unauthorized deviations in the speed comparator SPC, a second error signal FEG is output to the error collector FES. If the entry conditions are fulfilled, the interface INF generates an entry signal EBE and if the adjustment conditions are fulfilled, the interface INF generates an adjustment signal EBN. The door contacts are only bridged if the first enable signal ENE and the entry signal EBE or the second enable signal ENN and the readjustment signal EBN are present at the relay logic REL at the same time. A fault in the relay logic REL triggers a third error signal REF. If there are errors in the FES error collector, a fourth error signal REO switches the relay 16 off via the relay logic REL.

The CCD sensor 10, 11, which consists of a field of the image elements 19 converting the incident light into charges, captures an image of the code 3 arranged on the reflector 2. FIG. 4 shows a section of such an image in which a specific pattern with bright areas HB , Dark areas DB, light mids HM and dark mids DM is included. As shown in FIG. 5, the image of the CCD sensor 10, 11 is analyzed cyclically by the pattern recognition logic MER and by the computer CPU and the hardware is subjected to a cyclical test. By turning on the Supply voltage of the evaluation device 7, the program sequence is started with step S0.0. In step S0.1, hardware and software initialization is carried out. A hardware test of the RAM, ROM, register etc. is then carried out in step S0.2. After a successful test, the endless loop comprising steps S1 to S13 is carried out. The endless loop has an approximately constant throughput time. Interrupts for time control are not permitted since the evaluation unit 7 is a safety-relevant device. If the captured image with the pattern of step S1 has clear bright areas HB and dark areas DB, the lengths of the bright areas HB and the dark areas DB and a pattern repetition distance MW determined by the distance between the dark centers DM are determined. In addition, the light centers HM and the dark centers DM are checked for uniformity by determining the percentage of the picture elements 19 with the same brightness values. For further processing, the data determined by the pattern recognition logic MER are transferred to the data memory RAM via the bus system BUS.

In step S2, the computer CPU then compares the determined pattern with a reference pattern stored in the program and parameter memory ROM. For safety reasons, the uniformity of the light centers HM and the dark centers DM is also assessed in step S3. A too low percentage of the picture elements 19 with the same brightness values does not meet the entry and readjustment conditions. In the event of negative results of test steps S1 to S3, the entry condition or the adjustment condition are kept as not fulfilled via the INF interface. In step S4, the determined current pattern is compared with the last determined pattern and from this the shift of the determined Pattern calculated. The current speed v of the elevator car 6 is calculated from the displacement and a sampling cycle time t _A in step S5. In step S6 it is checked whether a pattern from the adjustment range B _{N has been} detected. If there is a positive test result of step S6, the current car speed v is compared in step S7 with the permitted speed v _n for adjusting the elevator car 6. A positive test result of step S7 triggers step S8, in which retraction and readjustment are communicated as permitted to the interface INF, which in step S9 outputs the entry signal EBE and the adjustment signal EBN to the relay logic REL. A negative test result of steps S6 and S7 initialize step S10, in which the current car speed v is compared with the permitted speed v _e for entering the elevator car 6. If the test step S10 has a negative result, the entry condition is kept as not fulfilled via the INF interface. A positive test result in step S10 triggers step S11, in which entry INF is communicated as permitted, which in step S9 outputs the entry signal EBE to the relay logic REL. If an entry signal EBE or an adjustment signal EBN and a first release signal ENE or a second release signal ENN and no error signal REO is present, the relay 16 is switched on and the door contacts 17 are bridged.

The calculation of the position of the elevator car 6 is not shown in the flowchart in FIG. 5. It can be easily derived on the basis of the first pattern detected and the calculated pattern repetition distance MW. The position signal POS derived therefrom not only serves for comparison with the position signal of the second channel but can also be used for fine positioning of the elevator car when entering the elevator control.

The hardware test of the RAM, ROM, register, etc., carried out in step S12 takes a long time overall. So that the endless loop consisting of steps S1 to S13 can be run through in a short and constant time, the hardware test is divided into test sections of the same duration. 6 shows an example with six test sections AS1 ... AS6. A variable shown as pointer ZEI points to the current test section AS2. When running through the loop, the ZEI pointer is set to the next section after the current test section has been processed, so that another test section is tested during the next loop run. In the present example, the entire test was carried out once after six loop runs. In step S13, the data determined in this way are output via the interface INF to the position comparator POC and to the speed comparator SPC.

Claims (8)

Method for generating shaft information for an elevator control of an elevator shaft (1) with an elevator car (6) which can be moved in the elevator shaft (1) and a readable code (3) arranged in the elevator shaft (1),
characterized,
that the code (3) is read image-wise, that at least one pattern contained in the image of the code (3) read is recognized,
that the recognized pattern is compared with a reference pattern and
that shaft information for elevator control is generated from the recognized pattern. Method according to claim 1,
characterized,
that at least one light area (HB) with a light center (HM) and at least one dark area (DB) with a dark center (DM) is recognized in the pattern and
that a pattern repetition distance (MW) is determined from the spacing of the dark centers (DM), from which the position of the elevator car (6) can be derived. Method according to claim 2,
characterized,
that the light centers (HM) and the dark centers (DM) are checked for uniformity by determining the percentage of the picture elements (19) with the same brightness values, the pattern being recognized as invalid for a certain percentage. Method according to claim 1,
characterized,
that a displacement of the current pattern compared to the last determined pattern is calculated and that a speed (v) of the elevator car (6) is calculated from the displacement and from a sampling cycle time (t _A ). Method according to claim 1,
characterized,
that an entry area (B _E ) and an adjustment area (B _N ) are recognized from at least one pattern, in which the bridging of door contacts (17) when entering the elevator car (6) into a stop is permitted. Process according to claims 4 and 5,
characterized,
that the speed (v) of the elevator car (6) is compared with a speed corresponding to the range (B _E , B _N ) and that entry and readjustment conditions are generated therefrom. Device for carrying out the method according to claim 1, comprising a readable code (3) arranged in the elevator shaft (1), a device for reading the code (3) arranged on an elevator car (6) movable in the elevator shaft (1) and a device for evaluation a shaft information contained in the code (3) for the elevator control,
characterized,
that at least one sensor (10, 12.2) is provided for reading the code (3) imagewise, that at least one device (MER) is provided for recognizing at least one pattern contained in the read image of the code (3) and that at least one computing device (CPU , ROM, RAM, BUS, INF) is provided for evaluating the shaft information contained in the sample. Device according to claim 7,
characterized,
that a first channel (13) with the sensor (10, 12.2), the computing device (CPU, ROM, RAM, BUS, INF), a relay logic (REL) for evaluating pattern-dependent signals (EBE, EBN, ENE, ENN) with a Relay (16) for bridging door contacts (17) is provided that a second channel (15) with the sensor (10, 12.2), the computing device (CPU, ROM, RAM, BUS, INF), a relay logic (REL) Evaluation of pattern-dependent signals (EBE, EBN, ENE, ENN) with a relay (16) for bridging door contacts (17) is provided and that a comparator (14) with a position comparator (POC) for comparing patterns of the channels (13 , 15) generated position signals (POS) and with a speed comparator (SPC) for comparing speed signals (SPE) generated from patterns of the channels (13, 15), error signals (FEP, FEG) from an error collector ( FES) of the comparator (14) are recorded and a Error signal (REO) from the error collector (FES) blocks the relay logic (REL) of the channels (13, 15) for bridging the door contacts (17).

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