METHOD FOR ACQUIRING AND PROCESSING ELEVATOR DATA OF AN ELEVATOR SYSTEM

Abstract

Methods and devices for optimizing control data of the elevator control unit of an existing or modernized elevator installation are described. An elevator control unit is connected to a programmable device. A three-dimensional digital replica data record, which can be generated by a computer program product, is loaded onto the programmable device as a simulation environment. The three-dimensional digital replica data record maps and simulates the existing or modernized elevator installation assigned to the elevator control unit. By testing the elevator control unit in the simulation environment, a parameter set for the elevator control unit of the existing or modernized elevator installation, which is matched for operation in the simulation environment, can be determined.

Claims

1. A method for optimizing control data of the elevator control of an existing or modernized elevator installation, wherein the elevator control unit is connected to a programmable device, the method comprising: loading a simulation environment based on a three-dimensional digital replica data record which can be generated by a computer program product, wherein the three-dimensional digital replica data record depicts and simulates the existing or modernized elevator installation associated with the elevator control unit, setting a parameter set for the elevator control unit of the existing or modernized elevator installation which is coordinated for operation in the simulation environment is determined by testing the elevator control unit in the simulation environment, wherein the three-dimensional digital replica data record of the existing or modernized elevator installation is constructed from component model data records which comprise different configurations and are defined by characterizing properties, approaching each floor level of the existing elevator installation at least once by at least one measuring run with the existing or to be modernized elevator installation, recording at least those measurement data representing floor heights by a measuring device, wherein: the component model data records configured as a floor section component model data record and/or the component model data records configured as a shaft section component model data record are arranged in a recorded sequence one above the other in the vertical direction for each floor level of the elevator installation detected by the measuring run, and the default values of the characterizing property that defines the height distance with respect to the next component model data record are replaced in these component model data records in each case by the corresponding floor heights determined from the measurement data.

2. The method according to claim 1, wherein the three-dimensional digital replica data record of the existing or modernized elevator installation is generated by the computer program product from component model data records and stored in a storage medium, wherein each characterizing property is predefined by a default value, predetermined by a target value, or is determined by an actual value.

3. The method according to claim 1, wherein each floor section component model data record or each shaft section component model data record has predefined interfaces via which interfaces of component model data records can be connected to one another and positioned relative to one another, corresponding characterizing properties of each component model data record to be added being automatically replicated with the corresponding characterizing properties of the component model data record provided for the connection via the interface.

4. The method according to claim 1, wherein at least one component model data record configured as an elevator cab component model data record and one component model data record configured as a suspension device component model data record is arranged in a virtual shaft formed by at least one shaft section component model data record, the characterizing properties of which include at least parameters that can be changed during the execution of the method and are part of the parameter set to be determined.

5. The method according to any of claim 1, wherein the three-dimensional digital replica data record can be retrieved from a storage medium and can be represented on a screen dynamically reproducing at least the floor heights of the floor levels as a virtual elevator installation in correct relationship to one another and the parameter set of the elevator control unit.

6. The method according to claim 1, wherein via a graphical user interface, further component model data records of components of an elevator installation are selected from a database and via predefined interfaces can be inserted into the three-dimensional digital replica data record.

7. The method according to claim 6, wherein there can be selection of components from among at least counterweight, guide rail, shaft door, cab door, and suspension means component model data records as component model data records in different suspension means guiding options.

8. The method according to claim 1, wherein the characterizing properties defined by measurement data or customer-specific configuration data are provided with a designation so that they can be distinguished from characterizing properties with default values.

9. The method according to claim 8, wherein a component model data record of the three-dimensional digital replica data record can be replaced by a definitive component model data record by its characterizing properties provided with a designation being read out via an exchange routine, based on these designated, characterizing properties from a database possible definitive component model data records matching the characterizing properties of actually existing components of elevator installations are determined, and the replacing component model data record is additionally selected where appropriate by manual inputs.

10. The method according to claim 1, wherein the parameter set is determined in the simulation environment using an optimization routine according to specifiable quality criteria.

11. (canceled)

12. A computer-readable medium having stored thereon machine-readable instructions, which executed on a programmable device, cause the programmable device to carry out or control a method according to any of claim 1.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0056] Embodiments of the disclosure will be described in the following with reference to the accompanying drawings, although neither the drawings nor the description should be construed as limiting the disclosure.

[0057] FIG. 1 shows schematically in three-dimensional view, an existing or modernized elevator installation, the elevator shaft being shown only schematically for the sake of clarity and the floors to be connected to the elevator installation only being indicated with a broken line;

[0058] FIGS. 2A to 2D show schematically example method steps for creating a three-dimensional digital replica data record of a modernized elevator installation or the existing elevator installation shown in FIG. 1;

[0059] FIG. 3 shows schematically in three-dimensional view the substantial components of a system that is suitable for performing the method shown in FIGS. 2A to 2D; and

[0060] FIG. 4 shows schematically different speed profiles of a particular floor section, the optimal parameter set of the elevator control unit for this floor section being determined in the simulation environment of the three-dimensional digital replica data record by means of an optimization routine according to specifiable quality criteria.

DETAILED DESCRIPTION

[0061] FIG. 1 shows schematically a three-dimensional view of an existing or modernized elevator installation 11, the elevator shaft 19 of which being only shown schematically for the sake of clarity and the floors 21, 23, 25, 27 created on site to be connected to the elevator installation 11 being only indicated with a broken line.

[0062] The elevator installation 11 comprises many different components which are arranged in the elevator shaft 19 which is usually created on site. These also include all the components listed in this paragraph, such as guide rails 37 mounted on the walls of the elevator shaft 19, an elevator cab 43 guided on the guide rails 37 and a counterweight 35 guided on the guide rails 37. The counterweight 35 is connected to the elevator cab 43 in a load-bearing manner by a suspension device 31, for example a steel cable or a belt. In the present exemplary embodiment, the suspension device 31 is guided in a so-called 2:1 suspension arrangement over deflection rollers 49 and a traction sheave 51. Of course, other suspension device guiding options such as 1:1, 3:1 and so forth are also possible. The traction sheave 51 is driven by a drive unit 39, which usually comprises a service brake 53, a reduction gear 55 and a drive motor 57. The drive motor 57 is driven by an elevator control unit 41. In the present exemplary embodiment, the drive unit 39 and the elevator control unit 41 are arranged in a machine room 29 which is located exactly above the shaft head 59 of the elevator shaft 19. The elevator cab 43 has cab doors 45 which can be temporarily coupled to shaft doors 61 (see FIGS. 2A and 3) arranged on the floors 21, 23, 25, 27. There are also safety devices 33 that monitor the correct functioning of the existing elevator installation.

[0063] Depending on the design of the elevator installation 11, noise problems or vibration problems can occur if the parameter set 207 of the elevator control unit 41 is not optimally configured for the configuration of the elevator installation 11. Such noise problems are significantly caused by the interaction of the elastic and geometric properties of the suspension device 31, by the load or force acting on the suspension device 31 from the elevator cab 43 and by a speed profile of the elevator cab 43, which is specified by the parameter set 207 of the elevator control unit 41. The geometric properties also include the length of the suspension device, the decisive factor being not the total length of the suspension device 31, but rather its partial sections, which in the exemplary embodiment shown extend between the deflection rollers 49.

[0064] Based on FIGS. 2A to 2D, possible method steps of the method 151 according to the disclosure for optimizing control data of an existing or modernized elevator installation 11 and an associated creation of a three-dimensional digital replica data record 111 of the existing or modernized elevator installation 11 shown in FIG. 1 are explained below. FIG. 2A again shows the existing or modernized elevator installation 11 in a simplified manner, only the outer contours of the elevator shaft 19, the floors of floor levels 21, 23, 25, 27, the elevator cab 43 and the shaft doors 61 and the machine room 29 being shown.

[0065] According to a possible embodiment of the disclosure, as shown in FIG. 2B, at least one measuring run 65 with the elevator cab 43 of the existing elevator installation 11 is used to approach each floor level 21, 23, 25, 27 of the elevator installation 11 at least once, and at least those measurement data G1, G2, G3, G4, h1, h2, h3 which represent floor heights h1, h2, h3 are recorded by means of a measuring device 63. In the present exemplary embodiment, the measuring device 63 is a data recording device which receives the measurement data G1, G2, G3, G4, h1, h2, h3 from the elevator control unit 41 or extracts them from control signals and sensor data transmitted to the elevator control unit 41 from sensors installed in the elevator installation 11 and stores them, or can forward these measurement data G1, G2, G3, G4, h1, h2, h3. For this purpose, the measuring device 63 can have a suitable computer program, which acts on the elevator control unit 41 of the existing elevator installation 11 and initiates the required measuring run 65. In this case, for example, the floor heights h1, h2, h3 can be read out directly from the control signals of the elevator control unit 41 as measurement data h1, h2, h3 which are transmitted, for example, from a shaft information system (not shown) of the existing elevator installation 11 to the elevator control unit 41. Furthermore, the motion profiles can be recorded as measurement data G1, G2, G3, G4. Since these represent the speed V of the elevator cab 43 over time t, the floor heights h1, h2, h3 can of course also be calculated from these measurement data G1, G2, G3, G4.

[0066] Of course, the measuring run 65 may also be carried out without measurement data G1, G2, G3, G4, h1, h2, h3 being read out from the elevator control unit 41 of the existing elevator installation 11. For this purpose, for example, a technician 71 can enter the elevator cab 43 with his mobile phone (smartphone) and carry out the measuring run 65 with the existing elevator installation 11. The mobile phone as the measuring device 73 records the acceleration and deceleration profile and the travel time from floor level to floor level or the motion profiles as measurement data G1, G2, G3, G4. He preferably places the mobile phone or the measuring device 73 on the floor of the elevator cab 43 during the measuring run 65 in order not to falsify the measurement data G1, G2, G3, G4. The floor heights h1, h2, h3 of the individual floor levels 21, 23, 25, 27 can in turn be calculated from these measurement data G1, G2, G3, G4.

[0067] According to a further possible embodiment of the disclosure, a three-dimensional digital replica data record 111 can also be created on the basis of a modernized elevator installation 11. In this case, the customer-specific configuration data 178 required for planning are used, which have been created by the customer or in cooperation with the customer. Logically, the number of floor levels 21, 23, 25, 27 and their floor heights h1, h2, h3 do not have to be determined by means of a measuring run 65, but can be found directly in the customer-specific configuration data 178.

[0068] As shown in FIG. 2C, taking into account these measurement data G1, G2, G3, G4, h1, h2, h3 or the customer-specific configuration data 178, a three-dimensional digital replica data record 111 can be assembled step by step from component model data records 112 and stored in a storage medium 101 (see FIG. 3). The component model data records 112 can have different configurations and are defined by characterizing properties B, T, H, wherein each characterizing property is predefined by a default value x, y, z, by a target value a, b, c, or is determined by an actual value q, r, s (see FIG. 3).

[0069] The characterizing properties B, T, H that define the nature of the component model data records 112 can be, for example, geometric dimensions of the components they represent, weights of the components they represent, material properties of the components they represent, and/or surface properties of the components they represent. Of course, dynamic information, such as the motion profiles already mentioned, can also be assigned to a component model data record 112 as characterizing properties and characterize its dynamic behavior. In other words, a plurality of characterizing properties B, T, H of one component or of a plurality of components of the elevator installation 11 can be determined and stored as measurement data G2, G3, G4, h1, h2, h3 or data a, b, c derived from customer-specific configuration data 187 in the three-dimensional digital replica data record 111. Geometric dimensions of the components can be, for example, a length, a width, a height, a depth, a cross section, radii, fillets, etc. of the components. Material properties of the components can be, for example, a type of material used to form a component or a partial area of a component. Furthermore, material properties can also be strength properties, hardness properties, electrical properties, magnetic properties, optical properties, elastic properties, etc. of the components. Surface properties of the components can be, for example, roughness, textures, coatings, colors, reflectivities, etc. of the components. The characterizing properties B, T, H can refer to individual components or component groups. For example, the characterizing properties B, T, H can relate to individual components from which larger, more complex component groups are composed. As an alternative or in addition, the characterizing properties B, T, H may also refer to more complex equipment composed of a plurality of components, such as drive motors, gear units, suspension device, etc.

[0070] In order to assemble the three-dimensional digital replica data record 111, in each case a component model data record 112 configured as a floor section component model data record 121, 123, 125, 127 can be arranged in the recorded sequence, or the sequence resulting from the customer-specific configuration data 187, one above the other in the vertical direction for each floor level 21, 23, 25, 27 of the elevator installation 11, wherein for this purpose interface information 131 which is correctly arranged and consolidated is preferably defined on the floor section component model data record 121, 123, 125, 127, for example, with the aid of a rule set 133. As already mentioned, component model data records 112 are defined by characterizing properties B, T, H, and these characterizing properties B, T, H are in turn predefined by default values x, y, z. In the present exemplary embodiment in FIG. 2C, the floor section component model data records 121, 123, 125, 127 are defined by two surfaces P and Q arranged at right angles to one another, the planar dimensions of which are each predefined by the characterizing properties width B, depth T, and height H with a corresponding default value x, y, z. Accordingly, this three-dimensional digital replica data record 111 or the virtual model thus created, which can be represented in three dimensions, initially only correctly displays the number of floor levels 21, 23, 25, 27 of the elevator installation 11.

[0071] As FIG. 2D shows, the three-dimensional digital replica data record 111 or this virtual model which can be represented three-dimensionally is now gradually refined and specified by the default value z of the characterizing property height H of each floor section component model data record 121, 123, 125, 127 which defines the height distance to the next floor section component model data record being replaced by the corresponding floor heights h1, h2, h3 determined from the measurement data G1, G2, G3, G4, h1, h2, h3 or customer-specific configuration data 187. On the basis of the floor heights h1, h2, h3 shown in FIG. 2D, it is evident that they differ significantly from the default values x, y, z of FIG. 2C and also from one another.

[0072] It can also be seen that the floor height h4 of the top floor level 27 of an existing elevator installation 11 cannot be calculated or defined by the measurement data G1, G2, G3, G4, h1, h2, h3 determined by means of a measuring run 65. For example, the technician must measure this floor height h4 manually and record it as measurement data h4 or its default value z is initially maintained until further measurement data on this characterizing property height H of the top floor level 27 are available. In modernized elevator installations, the target value for this floor height h4 can be determined from the customer-specific configuration data 187. Those characterizing properties B, T, H whose default values x, y, z have been replaced by measurement data G1, G2, G3, G4, h1, h2, h3 or target values h4 can be provided with a designation, as shown symbolically in the present exemplary embodiment with an asterisk as h1*, h2*, h3*, h4*. Such a designation * can be a code portion, a prefix, a suffix, and the like.

[0073] As discussed previously, each floor section component model data record 121, 123, 125, 127 has predefined interfaces 131. These serve not only as reciprocal positioning points when the floor section component model data records 121, 123, 125, 127 are combined, but also as interfaces 131 when additional component model data records 112 are added. As shown in FIG. 2D, a component model data record 112 configured as a shaft section component model data record 141, 143, 145, 147 can now also be added to these interfaces 131. The default value x, y, z of a characterizing property B, T, H of the shaft section component model data record 141, 143, 145, 147 connected to its interfaces 131 and which defines the shaft section height, is replaced or replicated by the corresponding floor height h1, h2, h3, h4 of the floor section component model data record 121, 123, 125, 127.

[0074] Of course, there is also the possibility of directly using, instead of the floor section component model data records 121, 123, 125, 127 described above, a shaft component model data record or a plurality of shaft component model data records 141, 143, 145, 147 as a component model data record 112. These preferably also have the characterizing properties B, T, H in the sense of the floor section component model data records 121, 123, 125, 127 and the interfaces 131 in order to be able to correctly create the three-dimensional digital replica data record 111 and to correctly reflect at least the number of floor levels and the floor heights h1, h2, h3, z.

[0075] In principle, each component model data record 112, depending on its configuration, can have a plurality of interfaces 131, 135 for adding further component model data records 112. For example, the shaft section component model data records 141, 143, 145, 147 can have—in addition to the interfaces 131 matching the floor section component model data records 141, 143, 145, 147 and/or each other—also interfaces 135 for shaft door component model data records 161. Information about which component model data records 112 are arranged at which interfaces 131, 135 of other component model data records 112 can be stored in the rule set 133 of the computer program product 109 described below. Like a higher-level parts list and building instructions, this rule set 133 defines the structure of the three-dimensional digital replica data record 111. As indicated in FIG. 2D, a sufficiently defined, created three-dimensional digital replica data record 111 can now be used as a simulation environment 250 for optimizing control data, for example using the optimization routine 209 described in more detail in FIG. 4.

[0076] The simulation environment 250 is substantially formed by the three-dimensional digital replica data record 111. However, additional data records may be required in order to bring the three-dimensional digital replica data record 111 into a so-called “executable state” so that it can be used as a simulation environment 250 for static and dynamic simulations. Such additional data records can be storage instructions, imaging instructions, simulation instructions, communication instructions with output and input units, compilation instructions, interface protocols, and the like. These data records can also be part of the computer program product 109 and can implement at least partial steps of the method 151 according to the disclosure.

[0077] FIG. 3 schematically shows in a three-dimensional view the substantial components of a system 1 which is suitable for carrying out the method 151 shown in FIGS. 2A to 2D. This system 1 for optimizing control data of an elevator control unit 41 with regard to an assigned existing or modernized elevator installation 11 can substantially have the following system parts: [0078] a programmable device 101; and [0079] a computer program product 109 with machine-readable program instructions 107.

[0080] In addition, the system 1 can have at least one measuring device 63, by means of which at least one measuring run 65 with the existing elevator installation 11 can be used to record at least those measurement data h1, h2, h3 from which floor heights h1, h2, h3 of the floor levels 21, 23, 25, 27 of the elevator installation 11 can be determined.

[0081] As already mentioned in the description of FIG. 2, the measuring device 63 of the depicted exemplary embodiment accesses measurement data G1, G2, G3, G4, h1, h2, h3 of the elevator control unit 41 of the existing elevator installation 11 and transmits it, symbolically represented by the double arrow 113, to the programmable device 101.

[0082] The programmable device 101 can be a single device such as, for example, a personal computer, a laptop, a mobile phone, a tablet, the elevator control unit 41 of the existing elevator installation 11, or the like. However, the programmable device 101 can also comprise one or more computers. In particular, the programmable device 101, as shown in FIG. 3, can be formed from a computer network which processes data in the form of a data cloud. For this purpose, the programmable device 101 can have a storage medium 115 in which the data of the digital replica data record 111 and the component model data records 112 of various configurations required for its creation can be stored, for example, in electronic or magnetic form. The programmable device 101 can also have data processing options. For example, the programmable device 101 can have a processor 117, with the aid of which data all of these component model data records 112 and the machine-readable program instructions 107 of the computer program product 109, in particular also program instructions for optimizing the control data or for generating a parameter set 207 having parameters pa, pt, pd and being matched to the three-dimensional digital replica data record 111 (see FIG. 4) can be processed. The optimized parameter set 207 can subsequently be implemented in the elevator control unit 63.

[0083] The programmable device 101 can also have the device interfaces symbolically represented by the double arrow 119, via which data can be input into the programmable device 101 and/or output from the programmable device 101. The programmable device 101 can also be implemented in a spatially distributed manner, for example when data is processed in a data cloud distributed over a plurality of computers.

[0084] In particular, the programmable device 101 can be programmable, that is, it can be prompted by a suitably programmed computer program product 109 to execute or control computer-processable steps and data of the method 151 according to the disclosure. The computer program product 109 can contain instructions or code which, for example, cause the processor 117 of the programmable device 101 to create, store, read out, process, modify data of a three-dimensional digital replica data record 111, set up a simulation environment 250 on the basis of the three-dimensional digital replica data record 111, carry out optimization routines 209 etc. In particular, the computer program product 109 can be written in any computer language.

[0085] The machine-readable program instructions 107 of the computer program product 109 reproduce in particular also the method steps of the method 151 according to the disclosure, shown by way of example in FIGS. 2A to 2D, in a machine-processable manner. Furthermore, the machine-readable program instructions 107 may have a large number of other program routines, such as various conversion routines for determining a floor height h1, h2, h3 from a motion profile G1, G2, G3, G4 (see FIG. 2B), control routines for controlling the interactions between the elevator control unit 41 and the measuring device 63, assignment routines which check the arrangement of component model data records 112 for their compatibility, rule sets 133 (see also FIG. 2C), collision check routines which check static and dynamic characterizing properties of the component model data records 112 arranged in the three-dimensional space with respect to one another, transmission protocols, control routines for the device interfaces, instruction routines for the technician, and the like.

[0086] By executing the computer program product 109 on the programmable device 101, taking into account the measurement data recorded by the measuring device 63, a three-dimensional digital replica data record 111 can be assembled from component model data records 112 and stored in the storage medium 115 of the programmable device 101. Here, the component model data records 112 can have different configurations and be configured, for example, as a floor section component model data record 121, 123, 125, 127, shaft section component model data record 141, 143, 145, 147, elevator cab component model data record 153, cab door component model data record 163, shaft door component model data record 161, drive component model data record 155 and so forth and can be defined by characterizing properties N, O, P, which are predefined with default values q, r, s.

[0087] For each floor level 21, 23, 25, 27 of an existing elevator installation 11 detected by the measuring run 65, in each case a component model data record 112 configured as a floor section component model data record 121, 123, 125, 127 is arranged one above the other in the vertical direction in the recorded sequence in the three-dimensional digital replica data record 111 created by the programmable device 101. In a modernized elevator installation 11, the customer-specific configuration data 187 are used for this. As shown in FIGS. 2A to 2D, the default value z of its characterizing property H, which defines the height distance to the next floor section component model data record, is replaced in each case by the corresponding floor height h1, h2, h3 determined from the measurement data G1, G2, G3, G4, h1, h2, h3.

[0088] Furthermore, a component model data record configured as an elevator cab component model data record 153 can be arranged in the virtual shaft formed by at least one shaft component model data record 141, 143, 145, 147. The individual motion profiles or parameters pa, pt, pd calculated by the simulation can also be assigned to the elevator cab component model data record 153 in the order of the floor component model data records 121, 123, 125, 127 as characterizing properties. This can mean that dynamic properties relative to the shaft component model data records 141, 143, 145, 147 are assigned to the elevator cab component model data record 153, so that the three-dimensional digital replica data record 111 with partially dynamic or movable component model data records 112 can be displayed on a screen 171, for example.

[0089] In other words, the three-dimensional digital replica data record 111 can be called up from the storage medium 115 and, as a virtual elevator installation, at least the floor heights between the floor levels can be displayed statically and/or dynamically on a screen 171 in a correct ratio. Due to the dynamic properties, the virtual elevator cab displayed on the screen 171 by the elevator cab component model data record 153 can also execute the same movements with the same directions of movement, accelerations, speeds and decelerations as the elevator cab 43 of the existing or modernized elevator installation 11 within the virtual elevator shaft formed by the shaft component model data records 141, 143, 145, 147.

[0090] Furthermore, spatial dimensions of the elevator cab 43 measured by the technician or extracted from plans and CAD files can be recorded as measured values u, v, w, and the default values q, r, s of the assigned, characterizing properties N, O, P of the elevator cab component model data record 153 can be replaced by the measured spatial dimensions, the default values x, y, z of the characterizing properties T, B, H of the shaft section component model data records 141, 143, 145, 147 or of the shaft component model data record being checked and, in the case of colliding dimensions, corresponding characterizing properties T, B, H being adapted to the projections of the characterizing properties N, O, P of the elevator cab component model data record 153 which lead to collisions. In particular, the cross section of the shaft section component model data records 141, 143, 145, 147, which is still defined by default values x, y, can be too small for the actual dimensions of the elevator cab 43. If necessary, a required play between the cab walls and the shaft walls can be added to the cab dimensions as standard in order to determine the characterizing properties T, B of the shaft section component model data records 141, 143, 145, 147 that characterize the shaft cross section, starting from the elevator cab 43.

[0091] In order to further simplify the creation of the three-dimensional digital replica data record 111, further component model data records 112 of components of an elevator installation can be selected from a database 175 via a graphical user interface 173 of an input interface/output interface 103 such as the illustrated laptop and inserted into the three-dimensional digital replica data record 111 via predefined interfaces 131, 135. Components of existing elevator installations 11 depicted in the database 175 as component model data records 112—such as various counterweight component model data records 177, guide rail component model data records 179, shaft door component model data records 161, cab door component model data records 163, drive component model data records 181 and suspension device component model data records 183 in various suspension device guiding options—can be available for selection.

[0092] The component model data records of actually existing components that can be called up from the database 175 can have completely determined characterizing properties N, O, P having actual values based on measurement results. To further improve the digital replica data record 111, its component model data records 112, which have mixed characterizing properties N, O, P determined with actual values u, v, w and pre-determined with the default values q, r, s, can be replaced by a definitive component model data record 181, 183, 153 from the database 175 with determined characterizing properties N, O, P. This can be done automatically by the characterizing properties N, O, P provided with a designation * being read out by an exchange routine 189 and, on the basis of these labeled, characterizing properties from the database 175, possible definitive component model data records 181, 183, 153 of actually existing components of elevator installations 11 that match the characterizing properties N, O, P are determined. Subsequently, the replacement component model data record 112 can, where appropriate, be additionally selected from these proposed definitive component model data records 181, 183, 153 by manual inputs. After selection, the replacement routine 189 can automatically delete the component model data record 112 to be exchanged and insert the replacement component model data record 112. In some cases, there are also identifying marks on components of the existing elevator installation 11, such as barcodes, matrix codes, RFID tags and the like, which allow a clear selection and use of the component model data record 112 representing this component by suitable detection in the system 1.

[0093] The computer program product 109 may be or may have been stored on any computer-readable medium 105.

[0094] By means of FIG. 4, by means of various speed profiles G2A, G2B, G2C of a certain floor section of the existing or modernized elevator installation 11 (see FIGS. 1 to 3) it shall be explained below how the optimal parameter set 207 for this floor section in the building can be determined by an optimization routine 209 according to specifiable quality criteria ΔQ in the simulation environment 250 using the three-dimensional digital replica data record 111. The double arrow 251 symbolizes the interaction between the optimization routine 209 and the simulation environment 250.

[0095] Strictly speaking, only one parameter set 207 is required to generate an optimal speed profile G2 for this shaft section. However, in order to be able to better explain the different stages of parameter set 207, the reference numerals of the related features “speed profile G2” and “parameter set 207” were added alphanumerically.

[0096] As already described in detail, the three-dimensional digital replica data record 111 of the existing or modernized elevator installation 11 now provides a simulation environment 250, by means of which various states of the existing or modernized elevator installation 11 can be checked dynamically. This can mean that test results no longer simply have to be extrapolated from the test tower, but that the behavior of the parameter set 207 implemented in the elevator control unit 41 can be checked and optimized by means of the interactions of the components or component model data records 112 virtually available by means of the three-dimensional digital replica data record 111.

[0097] In order for the optimization routine 209 to be carried out, the elevator control unit 41 of the modernized or existing elevator installation 11 must be physically present and, as shown by the dash-and-dot line, connected to the programmable device 101. The simulation environment 250 is executable on the programmable device 101, which is also indicated by a dash-and-dot line, which in turn is based on the three-dimensional digital replica data record 111 that depicts the system.

[0098] The noise problem of an elevator installation 11 mentioned above arises, for example, from a vibration system of elevator cab 43 and suspension device 31, the complex relationships of which are explained in a rudimentary manner below.

[0099] The suspension device 31 has certain elastic properties in the longitudinal and transverse directions, a certain area moment of inertia given by its cross section and a length-dependent net weight. All of these features are also stored in the suspension device component model data record 183 of the digital replica data record 111 as characterizing properties. As already mentioned above, the height of the elevator shaft 27 and the individual floor heights h1, h2, h3, h4 are also shown as precisely as possible in the digital replica data record. The empty weight of the elevator cab 43 and its maximum possible payload can also be assigned to the elevator cab component model data record 153 as characterizing properties.

[0100] Excited by the travel in the elevator shaft 27 or in the elevator shaft component model data record 127 (for example, by means of frictional relationships stored as characterizing properties, between a guide shoe component model data record, not shown, which is connected via interfaces to the elevator cab component model data record 153 and a guide rail component model data record 179), the natural frequency of this vibration system can be reached with a certain suspension device length, so that the vibrations of the suspension device 31 resonate transversely to the longitudinal extent thereof. Using the modern, available simulation methods, which include, for example, finite element analyzes, a variety of different scenarios (different loading of the elevator cab, different speed profiles G2A, G2B, G2C, additional external influences defined by characterizing properties such as temperature, humidity, air pressure, and the like) can be dynamically calculated and simulated as an optimization routine 209 for each shaft section, so that ideal speed profiles G2A, G2B, G2C can be determined for each of these shaft sections and for travels that extend over a plurality of floor levels 21, 23, 25, 27, which can be stored as parameter sets 207 in the elevator control unit 41 and can be used by the latter.

[0101] Optimization routines 209 are preferably programmed such that a simulation is carried out in the simulation environment 250 with a parameter set 207, then the simulation results are evaluated using various analysis methods (stochastic methods, algorithms, fuzzy logic, etc.), including previous simulation results, and on the basis of these analysis results of the parameter set 207 is changed in order to test this in turn in the simulation environment 250. These so-called optimization or test loops are continued until the simulation results meet the specifiable quality criteria ΔQ.

[0102] In the present exemplary embodiment in FIG. 4, three speed profiles G2A, G2B, G2C of the elevator cab 43, or of their dynamically movable elevator cab component model data record 153, are shown between two specific floor levels and thus for a specific shaft section. The first speed profile G2A, shown with a broken line, shows the travel of the elevator cab 43, 153 with the parameter set 207A stored in the elevator control unit 41 as the basic setting. This defines an acceleration phase pa1, a driving phase pt1 without substantial acceleration or deceleration, and a deceleration phase pd1. In the dynamic simulation of a travel in the simulation environment 250 of the previously created digital replica data record 111, vibrations 201 occur with this parameter set 207A, the amplitudes 203 of which exceed the limit band defined as quality criterion ΔQ. The consequences of these vibrations are noise problems in the elevator cab 43.

[0103] These problems could be remedied, for example, by a changed parameter set 207B with a changed acceleration phase pa2 and with a driving phase pt2 at a lower speed V. Such a parameter set 207B having the acceleration phase pa2, the driving phase pt2 and the deceleration phase pd2, which produces the speed profile G2B represented by a dash-dotted line, would be set by a technician on site after numerous tests on the elevator installation 11 in order to eliminate the noise problems. However, as the graphic shows by means of the two travel time ends t1, t2, the travel time between the two floor levels would be significantly longer and thereby the elevator installation 11 would be noticeably slower overall.

[0104] The method according to the disclosure can now be used to simulate a huge number of parameter sets 207, which ultimately results in a parameter set 207C which generates the third speed profile G2C represented by a solid line. Unlike the technician on site, who, for example, after two attempts using stronger acceleration phases (increase in the steepness of the acceleration curve in the speed-time diagram), recognizes that the amplitudes 203 of the vibrations increase even more and he/she therefore leaves this path, even stronger acceleration phases can be tested without damage by means of the simulation on the simulation environment 250. This allows an optimal parameter set 207C to be determined, in which the zone of the natural frequency of the elastic system of elevator cab 43 and suspension device 31 is passed through as quickly as possible in this shaft section in the acceleration phase pa3. As a result, a higher speed V can also be achieved in the driving phase pt3. Depending on the configuration of the deceleration phase pd3, the travel time t becomes shorter, as represented by the travel time end t3. In order to increase the driving comfort of the users, the deceleration phase pd3 can also be configured and checked by simulations, if necessary, so that the end of the travel time t3 is equal to the end of the travel time t1.

[0105] Of course, these simulations can be automated or at least partially automated in the sense of an optimization routine 209. This can mean that the computer program product 109 is programmed in such a way that it automatically compares the results obtained by the simulations with the specified quality criteria ΔQ and applies change tendencies of the simulation results with the common, well-known stochastic methods, with fuzzy logic, etc. to determine the next parameter set 207 provided for the simulation. As soon as all predetermined quality criteria ΔQ are complied with by the simulation result, the optimization routine 209 can be ended and the determined parameters pa3, pt3, pd3 can be transferred to the parameter set 207 for the elevator control unit 41 of the existing or modernized elevator installation 11, which is coordinated for operation in the simulation environment 250.

[0106] In other words, the parameter set 207 is determined in the simulation environment 250 using an optimization routine 209 according to specifiable quality criteria ΔQ. The specified quality criteria ΔQ are, for example, tolerance specifications with regard to the maximum permissible vibration amplitudes of the suspension device 31 and acceleration phases pa1, pa2, pa3 and deceleration phases pv1, pv2, pv3 of the elevator cab 43 that are pleasant for the user of the elevator installation 11 with the shortest possible duration of the travel. International, regional, and national standards such as EN-81 can also define quality criteria ΔQ such as the maximum permissible acceleration, decelerations, waiting times, door opening and closing times, and the like. All of these movement sequences, determined by the parameter set 207 of the elevator control unit 41, of the various movable components of an existing or modernized elevator installation 11 can be simulated, checked and optimized in the simulation environment 250 available through the three-dimensional digital replica data record 111.

[0107] Although the present disclosure has been described in FIGS. 1 to 4 using the example of a simple existing elevator installation 11 and using a simple digital replica data record 111 which depicts it and which is only rudimentary with a few component model data records 112, it is obvious that the described method 151 and the corresponding system 1 are equally also used for elevator installations 11 of more complex design. Even if only one elevator cab 43 is described and shown in the figures, the system 1 according to the disclosure and the method 151 according to the disclosure can of course also be used in existing and modernized elevator installations 11 with a plurality of elevator cabs 43.

[0108] Finally, it should be noted that terms such as “having,” “comprising,” etc. do not preclude other elements or steps and terms such as “a” or “an” do not preclude a plurality. Furthermore, it should be noted 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 embodiments described above. Reference numerals in the claims are not to be interpreted as delimiting.