EP1795482A1 - Installation system and method for elevators - Google Patents

Abstract

The invention relates to a method for starting up a conveyor system, the conveyor system comprises a plurality of components (21-27), wherein at least one means of transport, a system controller (20) and a drive are included; a control program (11) suitable for different plant controls (20) includes various control functions (12-18), wherein the control program (11) is operative to operate the conveyor in the plant controller (20), the method comprises the steps of: activating the conveyor ( S30); Identifying identification numbers (29) of components (21-27) of the conveyor (S31); Checking that the recognized identification numbers (29) belong to an approved component combination (S32); Recognizing the plant control type (11); Activating the various control functions (12-18) in the control program (11) depending on the detected control system type; Releasing the conveyor (S37).

Description

The invention relates to a conveyor system and a method for starting up a conveyor system.

Conveyor systems consist of a large number of different components. In particular, these include a means of transport, for example an elevator car or an escalator. Furthermore, a drive for the means of transport and a system control is provided. Optionally, communication and security components are arranged. To control the conveyor system, a control program is executed in the system control. The plant control has different functions.

Previously, when commissioning a conveyor system, the control program including the required drivers and functions was activated based on parameter settings. These parameter settings are stored in the system control. Alternatively, these parameter settings are created by the manufacturer during configuration and loaded into the controller. It is also possible to manually input the parameters to the plant controller so as to activate and set the control program for the plant control.

To minimize the development effort for control programs, it is common practice to use a control program for one type of conveyor. For example, a common control program is used for different elevator system controls. Another common control program is used for various escalator controls. Elevator systems must have many different functions. It is not in the individual applications necessary to realize all possible functions. However, the control program is designed to be able to control an elevator system in which all possible functions are realized. As an example of a simple realization of a transport system, one can cite a goods lift, which is only moved between two storeys. The control effort is low in this case. In a passenger elevator in a high-rise building, the control effort is much higher. Such a passenger elevator has, for example, an elevator call control. Next safety circuits are required. Optionally, an air conditioning of the elevator cars may be present.

Previously, a common control program was used for a transportation system, regardless of what functions were implemented in the transportation system or not. The setting as to what functions are needed in the control program for the individual transport system was, as mentioned above, determined by parameters which were either programmed at the manufacturer or had to be entered manually during commissioning of the conveyor system.

However, due to the variety of different types of plant control with different functions in a conveyor, it is extremely important that the right type of plant control be recognized and the right functions activated for the particular conveyor. Such system control types are designed differently complex depending on the complexity. For example, a plant controller for the aforementioned freight elevator need not be able to control an air conditioner. A system control for the above-mentioned passenger elevator, however, is much more complex in terms of their functionality.

The different plant control types can only be operated with the appropriate control program, whereby the large number of possible functions can lead to misconfigurations, as there are dependencies between the individual functions in the control program and components of a conveyor system. However, the presence of many functions in the control program and many parameters also requires many rules. These are sources of error. Thus, a conveyor system where few or no parameters need to be set is a more reliable conveyor system.

The object of the invention is therefore to provide a method and a device which make it possible to detect the system control type in a special component combination of a conveyor system and to activate the correct control functions depending on the system control type, which correspond to this component combination. Control functions that are appropriate for uninstalled component combinations must remain disabled.

The object is solved by the features of the independent claims. Advantageous embodiments emerge from the subclaims.

The invention is based on the recognition that the error source of the manual input is excluded in a self-detection of the components of a conveyor system. Thus, a device according to the invention is safer and less error-prone. In addition, an additional risk of a hardware conflict for mismatched components in the installed component combination is reduced, thereby reducing the security risk. In particular, in the field of conveyors, which include elevator systems and escalators, safety risks are unacceptable.

The method guarantees that only the control functions of the control program intended for a particular component combination are executed in the plant control.

Control programs are subject to constant development. Individual functions of conveyors are developed further, which makes it necessary to adapt the control functions in the control program to the new components and, if necessary, also to change the drivers for controlling the new components. In this case, it is extremely important that when updating a driver in the system control, this driver is only loaded into the system control of the conveyor system and executed by it, even if this driver was also provided and tested for system control.

According to the invention, it is proposed that the components of the conveyor system have identification numbers which are recognized when activating the conveyor system. Based on the recognized identification numbers is determined whether the recognized identification numbers belong to an approved combination of components. Only when the recognized identification numbers belong to an approved combination of components, it is concluded from which type of plant control is present. If identification numbers are identified that do not belong to any approved combination of components, commissioning of the transport system will be interrupted. The approved component combinations are combinations of the components for which there is a plant control type capable of controlling that component. Tables can be created that list and represent the allowed component combinations for each plant control type.

After recognizing which plant control type is present, the recognized plant control type is set in the control program. Depending on the type of system control detected, the various control functions are activated in the control program. Only then is the release of the transport system.

In a particular embodiment of the invention, it is provided that only the drivers for the control functions are loaded into the system control, which were previously also activated as control functions. This ensures that only the correct drivers are loaded into the system controller.

In a further advantageous embodiment of the method according to the invention is checked after setting the system control type, if the detected combination of components with the activated control functions match. The control program contains the information for which plant control types the control program with the activated control functions is enabled. The conveyor system is only released when the component combinations and control functions are allowed, that is, when the component combinations are capable of performing these control functions. Tables can be created which list and represent the approved control functions for each plant control type.

In a further advantageous method of the invention, after a release of the conveyor system, the conveyor system is activated again. This restart of the conveyor system ensures loading of the updated drivers.

In an advantageous embodiment of the invention, the conveyor system is an elevator system. In an alternative embodiment of the invention, the conveyor system is an escalator.

The invention is also achieved by a conveyor system having a plurality of components, wherein at least one conveyor of a system controller and a drive are arranged and the system controller has a predetermined range of functions, wherein for operating the conveyor system suitable for different system controls Control program in the plant control is executable, which contains various control functions, wherein the components of the conveyor system identification numbers and is provided for activation of the conveyor system to recognize the identification numbers of the activated components and the control program contains a list for checking whether the identified identification numbers to belong to an approved combination of components and a plant control type depending on the recognized identification numbers in the control program is adjustable and the control functions contained in the control program can be activated depending on the plant control type, wherein a check is provided if the detected combination of components with the activated control functions matches and the conveyor system is releasable, if the combination and the activated control functions match.

Fig. 1

einen schematischen Aufbau eines Steuerungsprogramms mit unterschiedlichen Steuerungsfunktionen gemäß der vorliegenden Erfindung;

Fig. 2

eine schematische Darstellung der Komponenten einer Anlagensteuerung gemäß der vorliegenden Erfindung;

Fig. 3

ein Flussablaufdiagramm für die Inbetriebnahme einer Beförderungsanlage.

Fig. 4

Tabelle der relevanten Komponentenkombinationen für die Erkennung jedes Anlagensteuerungstyps.

The invention will be explained in more detail below with reference to exemplary embodiments, which are shown schematically in the drawings. Show here

Fig. 1

a schematic structure of a control program with different control functions according to the present invention;

Fig. 2

a schematic representation of the components of a plant control according to the present invention;

Fig. 3

a flow chart for the commissioning of a conveyor system.

Fig. 4

Table of relevant component combinations for the detection of each plant control type.

FIG. 1 shows the modular structure of a control program 11 in which different control functions 12 to 18 are implemented. Each control function 12 to 18 is responsible for a particular function of the conveyor. The control function 12 is responsible for the control of user interfaces in the transport system. The control function 13 is used for monitoring and the input and output control of parameters and operating variables to external and internal components. The control function 14 assumes the function I / O Plug & Play, for example the air conditioning of one or more elevator cars. The control function 15 controls a chip card reader. The control function 16 assumes a subgroup control for parts of an elevator installation. The control function 17 is used to supply information of a hoistway, which are recorded for example by means of sensors. The control function 18 controls the distance control between the car and the shaft. Another important control function is, for example, the control of the safety circuit.

The different modules or control functions 12-18 show different types of system control. It can be seen that various settings for the control functions 12-18 in the control program 11 are required for the different plant control types TXR5, TX-GC, MX-GC, MX-GC2, TX GC2_EUAP, TX GC2_NA and GX-GC. For example, in the control function 14, which is responsible for the air conditioning of the conveyor system, it can be seen that no air conditioning is provided for a controller TXR5. In another type of plant control, such as MX-GC 2, air conditioning is provided per elevator car. In another system control type GX-GC, a group air conditioning of several elevator cars is provided. Likewise, in the case of the control function 15 for the chip card reader, it can be seen that different chip card readers are used for different types of plant control. For example, it is recognizable in the TX-GC controller, that no chip card reader is required. The MX-GC system controller requires special settings for the chip card reader. It is easy to see that due to the large number of different types of control systems, the activation of the individual control functions 12-18 or of the control modules must be done with great care in order to avoid safety risks.

FIG. 2 shows a schematic representation of the various components of a system controller 20. The modules 21-23 are communication modules of the system controller. The system controller 20 includes a microprocessor 24 having an I ² C functionality 28. Identification numbers 29 on the individual components 21-27 which are stored in EEPROM memory modules of the individual components 21 to 27 are read out via this I ² C bus. The identification numbers 29 are identified by address points A0 to A2. By providing 3 bits, a sufficient number of different identification numbers can be provided. FIG. 2 shows the structure of a TX-GC system controller.

A component 25 is used for the safety circuit feed 25. Another component 26 is used for the safety control 26. Furthermore, a brake control 27 is provided.

A flowchart shown in FIG. 3 shows the sequence of a method according to the invention. In step S30, the procedure for starting up a conveyor is started. After the equipment has been activated, the components of the equipment are detected in step S31 by reading the stored identification numbers 29 of the installed components 21-27 through the microprocessor 24 via the I ² C bus. In step S32 it is checked whether the recognized combination of components represents a valid combination of components.

The approved or valid component combinations are combinations of the components for which there is a plant control type capable of controlling that component. A table is stored in the control software, which lists and displays the approved component combinations for each plant control type. The control software can thus detect whether the detected combination of components is valid and approved.

Such a table is similar to the table shown in Fig. 4, but which shows only the relevant combinations of components for the recognition of each type of plant control. When the control software detects the component combinations listed in FIG. 4, the control software may associate the combination with a particular plant control type. However, a particular type of plant control may still control many other allowed and valid combinations of components that have not been listed in FIG.

If it is not a valid component combination, a message is output to the service engineer via a display device in step S39, S41. If a valid component combination is present, it is checked in step S33 which control program is stored in the system control. In a further step S34, it is checked whether this software or the control program for the individually recognized component combination is enabled. If it is the wrong control program, a message is issued via a display device in steps S40, S41. If the control program for this combination of components is released, the components of the elevator installation are updated in step S35, if necessary. Thereafter, in step S36, the conveyor is restarted to enable proper start of all control functions, drivers, and components. In step S37, the conveyor is ready for use. In step S38, the program for startup is ended

Thus, a conveyor system and a method for commissioning a conveyor system are provided, in which it is ensured that only the control program is executed on the system controller, which is also released for the system control type. Further, thus, a common control program for different types of plant control can be used, in which case different development versions of the control program are tested and approved only for certain types of plant control. Thus, for a variety of different types of plant control, there is only a single control program that can be centrally developed, which makes it easier to troubleshoot the control program and to develop new control functions for all plant control types. By using version or generation numbers for the control program and the control functions, it can be easily and automatically determined at commissioning whether the generation of a control program can be used for a plant control type because the control program contains the information on which plant control types it is allowed to execute.

It is thus excluded that control functions are activated in the control program for uninstalled components. It also prevents unchecked or unwanted control functions from being available in a system control type that is not allowed, which would result in a security risk. The method according to the invention ensures that the check of which type of installation control is installed in the conveyor system is determined exclusively on the basis of the installed components. There is no interaction required by a service engineer.

Claims (7)

Method for starting a conveyor system, which comprises a plurality of components (21-27), wherein at least one conveyor, a system controller (20) and a drive are included, wherein a control program (11) suitable for different system controllers (20) has various control functions (12- 18), the control program (11) for operating the conveyor system being carried out in the system controller (20), comprising the following steps: - activation of the transport system (S30); - identifying identification numbers (29) of components (21-27) of the conveyor (S31); - checking whether the recognized identification numbers (29) belong to an approved component combination (S32); - recognizing the plant control type (11); - activating the various control functions (12-18) in the control program (11) depending on the detected control system type; - Releasing the transport system (S37). Method according to Claim 1, characterized in that drivers for the control functions (12-18) are loaded into the system controller (20) as a function of the activated control functions. A method according to claim 1 or 2, characterized in that after detecting (S32) the plant control type is checked (S33), which control program is stored in the plant controller (20) and whether the stored control program for the recognized component combination is valid (S34), whereby the transport system is released (S37) if component combinations and control functions are allowed. Method according to one of claims 1 to 3, characterized in that after updating of components (21-27) or control functions (12-18), the conveyor system is activated again. Method according to one of claims 1 to 4, characterized in that the conveyor system is an elevator system. Method according to one of claims 1 to 4, characterized in that the conveyor system is an escalator. A conveyor system with a plurality of components (21-27), wherein at least one conveyor, a system controller (20) and a drive are arranged and the system controller (20) has a predetermined range of functions, wherein for operating the conveyor system suitable for different system controls control program (11) in the system controller (20) is executable, which contains various control functions (12-18), wherein the components (21-27) of the conveyor system identification numbers (29) and is provided upon activation of the conveyor system, the identification numbers (29) of the activated Recognize components (21-27); and in the control program (11) a list is included for checking whether the recognized identification numbers (29) belong to an approved component combination and a plant control type in dependence on the recognized identification numbers (29) in the control program (11) is adjustable and the control functions contained in the control program Dependence of the system control type can be activated; wherein a check is provided as to whether the recognized component combination matches the activated control functions (12-18) and the conveyor is releasable if the combination of components and the activated control functions match.

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