EP1980520A1 - Method for adjusting a number of operating units of a lift facility with a number of floors - Google Patents

Abstract

The method involves connecting operating units (50-55) in series, and connecting the operating unit (50) connected to a central controller (40). Each operating unit is provided on each floor (12, 14, 16), and configuration data with an address data packet is sent from the controller to the operating units. A number of addresses are stored in the address data packet, where the addresses permit fixing of an address for each operating unit.

Description

The present invention relates to a method for setting a plurality of operating units of a lift system with a plurality of floors. Each floor is at least one control unit assigned. The invention further relates to such a lift installation.

As part of the installation and installation of an elevator system in a building, the elevator car during a so-called learning trip to all stop positions, d. H. on all floors, proceed to adjust the holding positions to the height levels of the respective floors. Furthermore, the distributed on the individual floors control units and their communication with the central control unit must be set or configured. In this case, it is necessary to define or arrange the operating units with regard to their position in a specific floor and with respect to their function, so that during later operation of the elevator installation the central control unit recognizes from which floor and from which operating unit a specific signal by actuating the operating unit transmitted by the user.

Conventionally, this adjustment is made by the fact that a fitter must enter data, for example by means of the elevator car tabling, and after approaching each floor in each floor, each control unit must be set manually. Configurations made in this way require a great deal of time and personnel.

The invention is therefore based on the object of developing a method for setting a plurality of operating units of an elevator installation in such a way that that the configuration of the operating units is possible in a simple way and in a shorter time.

1. a) Senden von Konfigurationsdaten mit einem Adressdatenpaket von der Steuereinheit zu den Bedieneinheiten , wobei das Adressdatenpaket eine Vielzahl von Adressen zur jeweiligen Festlegung einer Adresse für jede Bedieneinheit umfasst,
2. b) Speichern der Adresse in einer Speichereinheit der Bedieneinheiten.

To solve this problem is in a method for setting a plurality of control units, an elevator system with a plurality of floors, the control units are connected in series and a first control unit is connected to a central control unit, and wherein at least one control unit is assigned to a floor according to the invention, according to claim 1, that the method comprises the following steps:

1. a) sending configuration data with an address data packet from the control unit to the operating units, the address data packet comprising a plurality of addresses for respectively defining an address for each operating unit,
2. b) storing the address in a memory unit of the operating units.

With the method according to the invention, a comparatively simple, preferably fully automatic, and quickly implementable setting or configuration of the plurality of operating units distributed on the floors is made possible. So can be dispensed with a complex setting process with shutdown of the individual floors and manual adjustment of the control units. The method according to the invention only has to be started and can then proceed fully automatically. In addition, in this way any sources of error due to manual settings can be reduced.

A "control unit" in the sense of the present invention is understood to mean the panel provided in the access area of each floor to the elevator installation for the destination call input and / or optical and / or acoustic display units for the use of the elevator installation. Such a control unit usually comprises at least one print. Preferably, however, are There are two different prints on each floor, with one print forming a destination call tray and the other a print ad unit.

Advantageous developments of the method according to the invention are described in claims 2 to 8.

In an advantageous development of the method, it is provided that the addresses are stored in a specific order in the address data packet and are sent and / or stored step by step in the memory units in this order.

Advantageously, each memory unit comprises a shift register, wherein the shift registers are connected in series and the respective address is stored in the respective shift register. With such shift registers, there is the advantage that the content of such a shift register can be shifted by one or more locations. Such a shift register may be composed of a plurality of circuits (flip-flops). Such a flip-flop is bistable with the two states 0 and 1 and can be used to store one-bit long information.

The step-by-step storage preferably takes place as a function of a predetermined clock signal.

In a further advantageous development, it is provided that each operating unit sends a control signal to the control unit. This control signal can inform the central control unit that the respective control unit is functional. In this way, after completion of the setting procedure by the central control unit, it can be determined whether all the operating units are functional. If an operating unit is not functional and has not sent back a control signal, the control unit emits a corresponding signal which indicates that the setting has failed announces. Then, the non-functional control unit can be replaced and the configuration process can be restarted.

In a development of the method according to the invention, it is proposed that each operating unit sends an identification signal for designating the operating unit or its properties to the control unit. This identification signal may, for example, comprise a type or group category of the operating unit and identify, for example, a destination call tableau or a display unit. This marking can be stored in the central control unit.

Advantageously, each operating unit transmits a position data signal for designating a floor to the control unit. In this way, the central control unit recognizes which operating unit is present on which floor.

In a refinement of the method, it is proposed that at least two groups of operating units be provided, with a first group comprising a plurality of destination call tableaus and / or destination call terminals and a second group comprising a plurality of display units. With regard to the series connection of the operating units, respectively, the operating units of a group or the operating units of several groups, preferably all groups, can be connected in series.

Finally, the invention also relates to an elevator installation for carrying out the method described above.

Fig. 1

einen Ausschnitt eines Gebäudes mit einer Aufzugsanlage mit einer Vielzahl von Stockwerken und auf den Stockwerken verteilten Bedieneinheiten, und

Fig. 2

eine schematische Übersicht der bei dem Verfahren durchgeführten Schritte zur Einstellung der Bedieneinheiten der Aufzugsanlage gemäß Fig. 1.

The invention will be further explained with reference to the drawings. Show in it

Fig. 1

a section of a building with an elevator system with a variety of floors and on the floors distributed control units, and

Fig. 2

a schematic overview of the steps performed in the process for adjusting the operating units of the elevator system according to Fig. 1 ,

Fig. 1 schematically shows a section of a building 10 with an elevator system 20. The elevator system 20 includes a vertically movable elevator car 30 with a control panel 32 with multiple destination callers and a car door 34. The control panel 32 is in communication with a central control unit 40, which is used to control the elevator system 20 serves. The building 10 has three floors 12, 14, 16. On each of these floors 12, 14, 16 is in each case an access to the elevator installation 20, which can be closed in each case by means of an access door.

In the area of each access, there are two operating units on each floor 12, 14, 16. In detail, there are two operating units 50, 51 on the first floor 12, two operating units 52, 53 on the second floor 14 and two operating units 54, 55 on the third floor 16.
In this case, the operating units 51, 53 and 55 represent target call panels, via which the user of the elevator installation 20 can request the elevator car 30 and / or deliver a destination call. Each of the operating units 51, 53, 55 comprises a respective storage unit 61, 63, 65 in the form of a shift register 71, 73, 75 ("shift register") and a plurality of destination call buttons.

Furthermore, there is a second operating unit in the area of each access on each floor. These in the FIGS. 1 and 2 with the reference numerals 50, 52, 54 designated operating units represent display units and each comprise a memory unit 60, 62, 64 also in the form of a respective shift register 70, 72, 74 ("shift register").

Each shift register 70 to 75 has 8 series-connected flip-flops with a memory content of 1 bit each. Thus, each shift register 70-75 provides a memory content of 8 bits. The shift registers 70 to 75 can be written and read in parallel.

All of the aforementioned operating units 50 to 55 are connected in series via a data line 42, the first operating unit 50 being connected to the central control unit 40. Furthermore, the shift registers 70 to 75 are connected in series. The connection of the individual control units 50 to 55 with each other and the allocation of the individual control units 50 to 55 to the floors 12, 14, 16 can also be the scheme in Fig. 2 remove.

Based on this system, a method for setting the operating units 50 to 55 will be explained below.

In a first step, configuration data with an address data packet is sent from the control unit 40 to the shift registers (70-75) of the operating units (50-55). The address data packet includes a plurality of addresses for respectively setting an address for each operation unit 50 to 55. For example, the values 255 to 1 (255>254>253>...>3>2> 1) represent the addresses (in Fig. 2 labeled "ADDRESS" or "DATA"). Preferably, one of the number of operating units 50 to 55 or the shift registers 70 to 75 corresponding number of values, that is addresses, provided for the address data packet.

The storage of the addresses in the shift registers 70 to 75 of the memory units 60 to 65 is carried out stepwise in response to a predetermined clock signal, so that with each clock of the memory contents within a Shift register 70 to 75 shifted by a flip-flop (see Fig. 2 "CLK"). In this way, the addresses stored in a specific order in the address data packet can be processed according to this sequence at fixed time intervals and sent to memory units 60 to 65 and / or stored.

Thus, the first address "255" is initially stored in the shift register 70 of the first operating unit 50 by the address data packet. Subsequently, the address "254" is sent to the first operating unit 50 and the address "255", which is there in the first place in the address data packet, is shifted into the shift register 71 of the second operating unit 51. Subsequently, the address "253" is sent to the first operating unit 50, where the address "254" is shifted from the shift register 70 into the shift register 71. The address 255 located there is accordingly shifted into the shift register 72 of the third operating unit 52. In the same way, these steps are repeated for all addresses from 255 to 1. The addresses are sent stepwise in the order (255, 254 .... 2, 1) to the first operating unit, while the addresses stored in the other shift registers are successively shifted to the following shift register.

At the end of the method, therefore, the operating unit 50 located closest to the control unit 40 has the address "1", the operating unit 51 has the address "2", etc., until finally the operating unit 55 has the address "6". The addresses 7-255 no longer correspond to a register in the present example and are lost.

After each shift register 70 to 75 has been sent an address, the control unit 40 sends a signal to each operation unit 50 to 55 to read out the contents of the respective shift registers 70 to 75, and thus to allocate the predetermined address.

The control unit 40 can thereby recognize the type of operating unit and how many floors the building has.

After each operating unit 50 to 55 has been assigned an individual address, the control unit 40 can determine whether all operating units 50 to 55 are functional. Namely, if one of the operating units 50 to 55 is not functional, the configuration process can not be completed. However, it is readily possible to immediately determine which of the control units 50 to 55 is not working, so that they can be replaced immediately. Such a check is preferably made possible by the fact that each operating unit 50 to 55 sends a control signal to the control unit 40 in order to inform it of its functional capability.

In addition, it can be provided that each operating unit 50 to 55 sends an identification signal for designating the operating unit 50 to 55 to the control unit 40. This identification signal may include a hardware identifier. It can further be provided that each operating unit 50 to 55 transmits a position data signal for designating the floor on which the operating unit is located to the control unit 40. Thus, the control unit 40 recognizes which operating unit 50 to 55 is located at which position or on which floor.

The above-described method for setting the operating units 50 to 55 is characterized in particular by the fact that for setting the operating units 50 to 55 no separate setting of each operating unit 50 to 55 by assembly personnel and by driving off of the individual floors 12 to 16 is required. With the method according to the invention, this setting can be made automatically by sending the address data packet successively to the shift registers 70 to 75 of the individual operating units 50 to 55 as a result of the series connection of the operating units 50 to 55 and in each case in a specific order in the address data packet stored addresses are stored in the individual storage units 60 to 65. At the same time, in case of failure of the configuration process, it is easy to determine which of the operating units 50 to 55 may be defective.

Claims (9)

Method for setting a plurality of operating units (50, 51, 52, 53, 54, 55) of a lift installation (20) having a plurality of floors (12, 14, 16), wherein the operating units (50, 51, 52, 53, 54, 55) are connected in series and a first operating unit (50) is connected to a central control unit (40), and wherein in each case at least one control unit (50, 51, 52, 53, 54, 55) a floor (12, 14 , 16), the method comprising the steps of: a) sending configuration data with an address data packet from the control unit (40) to the operating units (50, 51, 52, 53, 54, 55), the address data packet having a plurality of addresses for respectively setting an address for each operating unit (50, 51 , 52, 53, 54, 55), b) storing the address in memory units (60, 61, 62, 63, 64, 65) of the operating units (50, 51, 52, 53, 54, 55). A method according to claim 1, characterized in that the addresses are stored in a specific order in the address data packet and are sent in this order step by step in the memory units (60 to 65) and / or stored. Method according to Claim 1 or 2, characterized in that each memory unit (60 to 65) comprises a shift register (70 to 75), wherein the shift registers (70 to 75) are connected in series and the respective address in the respective shift register (70 to 75) 75) is sent and / or stored. Method according to one of Claims 1 to 3, characterized in that the step-by-step transmission and / or storage takes place as a function of a pre-determined clock signal. Method according to one of claims 1 to 4, characterized in that each operating unit (50, 51, 52, 53, 54, 55) sends a control signal to the control unit (40). Method according to one of claims 1 to 5, characterized in that each operating unit (50, 51, 52, 53, 54, 55) an identification signal for designating the operating unit (50, 51, 52, 53, 54, 55) or their properties the control unit (40) sends. Method according to one of claims 1 to 6, characterized in that each operating unit (50, 51, 52, 53, 54, 55) sends a position data signal for designating a floor (12, 14, 16) to the control unit (40). Method according to one of claims 1 to 7, characterized in that at least two groups of operating units are provided, wherein a first group comprises a plurality of destination call tableaus (50, 52, 53) and / or destination call terminals and a second group comprises a plurality of display units (51, 53, 55). Elevator installation (20) for carrying out the method according to one of claims 1 to 8.

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