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[[de:Referenzaufzug]]
=Model lift system with CANopen components=
=Model lift system with CANopen components=


The Heilbronn University is known for many years through congresses and conferences in the field of elevators. Now, a research project is started, that aims at various aspects of the automation of elevators with CANopen, such as compliance testing "in the loop" and the possibilities of telemetry and remote diagnostics. Suggestions and discussions are currently on the project of Mr. Hellmich, Böhnke + Partner, Bergisch Gladbach.
The Heilbronn University is known for congresses and conferences in the field of elevators for many years. Now, a research project is started which aims various aspects of the automation of elevators with CANopen. Examples are compliance tests "in the loop" and the possibilities of telemetry and remote diagnostics. Suggestions and discussions on the project currently come from Mr. Hellmich, Böhnke + Partner, Bergisch Gladbach (now c/o [http://elfin.de elfin.de]).


''You too could be part of this project!''
''You could also be a part of this project!''


In order to obtain a realistic test environment, a group of four students from the master's degree courses in Mechanical Engineering and Mechatronics at the Heilbronn University under the direction of Prof. Dr.-Ing. Ansgar Meroth started a project in which an elevator system in 1:10 scale model is built and networked via CANopen original components. All components are concurrently simulated by a corresponding function in Vector CANoe and MathWorks Matlab / Simulink models, allowing to replace components in real time by simulated functions.
In order to obtain a realistic test environment, a group of four students from the master's degree courses in Mechanical Engineering and Mechatronics at the Heilbronn University under the direction of Prof. Dr.-Ing. Ansgar Meroth started a project in which an elevator system model on a scale of 1:10 is built and controlled via original CANopen components. All CANopen components are simultaneously simulated by a corresponding function model in Vector CANoe and MathWorks Matlab/Simulink, allowing to replace components by real time simulated functions.


The resulting model system shall demonstrate the CANopen standards and provide an opportunity to review new components for conformity. It differs fundamentally from a previous model, designed in the MG lift, by a higher mechanical detail. With its open architecture, a combination of both demonstrators is possible.
The resulting model system shall demonstrate the CANopen standards and provide an opportunity to review new components for conformity. It differs fundamentally from a previous model, designed in the MG lift, by a higher mechanical detail. With its open architecture, a combination of both demonstrators is possible.
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=Model=
=Model=


The objective of the model is to construct and build an elevator system in 1:10 scale. The model will show two shafts, each with three floors and a cabin per shaft. The functionality will correspond as far as possible to the actual features of real elevators. However, due to the miniaturization and the better handling all control panels and control units are not directly attached to the model, but separated in a separate cabinet.
The aim of the model is to construct and build an elevator system on a scale of 1:10. The model will show two shafts, each with three floors and one cabin per shaft. The functionality of the model will correspond as far as possible to the actual functionality of real elevators. However, due to the miniaturization and the better handling, all control panels and control units are not directly installed inside the model, but separated in a control cabinet.


Since the use of this model to fairs and exhibitions is possible and desirable, as many components will be provided with windows or transparent to allow a better insight. Furthermore, the model will be secured, so that visitors can not touch moving parts or electrical components. To permit the use at exhibitions, the model will be transportable. This leads to additional demands on the model. The model with dimensions of 1200 mm x 600 mm x 400 mm (HxWxD) is transportable. Consequently, splitting of the model and securing the movable parts is guaranteed.
Because the usage on fairs and exhibitions is possible and welcome, as many components as possible will be provided with windows or will be made of transparent material to allow a better insight. Furthermore, the model will be secured, so that visitors can not touch moving parts or electrical components. To enable the usage on exhibitions, the model will be transportable. This leads to additional demands on the model. The model with dimensions of 1200 mm x 600 mm x 400 mm (HxWxD) is transportable in a car. Furthermore, splitting of the model and securing the movable parts will be guaranteed.
 
A [[#Video|video]] of the model you can find at the end of this article.
 
=Control Units and Network=
All control units used in the demonstrator should be, as far as possible, original equipment of real CANopen lifts.
 
The project additionally aims a simulation of the model with all control units with the aid of Vector CANoe and MathWorks Matlab/Simulink. By monitoring the CAN signals of the demonstrator, both programs shall reflect the status of the system. Furthermore, additional control messages should be able to send from these programs to enable a remote control (e.g. call a lift). Thus, additional components or a third shaft may be simulated. In a follow-up project, remote diagnosis is planned.
 
 
[[file:Gesamt_Front-Ansicht_edit.jpg|300px|Gesamtmodell]]  [[file:Gesamt_iso-Ansicht_edit.jpg|300px|Gesamtmodell]]
 
 
 
[[file:Kabine_Front-Ansicht_edit.jpg|300px|Kabine]]  [[file:Kabine_in_schiene_iso-Ansicht_edit.jpg|300px|Kabine mit Führung]]
 
=Current Status of the Project=
Currently, the design of the system is made with CATIA V5 R19 by Dassault Systèmes.
 
Simultaneously, the Matlab/Simulink and CANoe models are built.


=Sponsors=
=Sponsors=
Because some components of the elevator model are very expensive, especially the electronic components, you are kindly invited to contribute with your products. We will attach your logo at a prominent place on the model to indicate you as a sponsor.


Because some components of the elevator model are very expensive, especially the electronic components,you are kindly invited to contribute with your products. We will attach your logo at a prominent place on the model to indicate you as a sponsor.
The following companies already contribute to the model:


The following companies already contribute to the model:
* Böhnke + Partner GmbH Steuerungssysteme
SICK AG (light curtain model for fusing)
* SCHAEFER GmbH
    ... To be continued with your help ....  
* SICK AG
* SafeLine Deutschland GmbH
* Henning GmbH & Co. KG
* Murrplastik Systemtechnik GmbH
* Weidmüller Interface GmbH & Co KG
* …to be continued with your help….
 
If you are interested in sponsoring this project, please contact Mr. Meroth at the following address: ansgar.meroth (at) hs-heilbronn.de
 
= Video =
In this video you can see the reference lift at work.  


If you are interested in becoming a sponsor, please contact Mr. Meroth at the following address: ansgar.meroth (at) hs-heilbronn.de
<youtube>YnMOXe3Q4h8</youtube>

Latest revision as of 13:41, 18 August 2014

Model lift system with CANopen components

The Heilbronn University is known for congresses and conferences in the field of elevators for many years. Now, a research project is started which aims various aspects of the automation of elevators with CANopen. Examples are compliance tests "in the loop" and the possibilities of telemetry and remote diagnostics. Suggestions and discussions on the project currently come from Mr. Hellmich, Böhnke + Partner, Bergisch Gladbach (now c/o elfin.de).

You could also be a part of this project!

In order to obtain a realistic test environment, a group of four students from the master's degree courses in Mechanical Engineering and Mechatronics at the Heilbronn University under the direction of Prof. Dr.-Ing. Ansgar Meroth started a project in which an elevator system model on a scale of 1:10 is built and controlled via original CANopen components. All CANopen components are simultaneously simulated by a corresponding function model in Vector CANoe and MathWorks Matlab/Simulink, allowing to replace components by real time simulated functions.

The resulting model system shall demonstrate the CANopen standards and provide an opportunity to review new components for conformity. It differs fundamentally from a previous model, designed in the MG lift, by a higher mechanical detail. With its open architecture, a combination of both demonstrators is possible.

Model

The aim of the model is to construct and build an elevator system on a scale of 1:10. The model will show two shafts, each with three floors and one cabin per shaft. The functionality of the model will correspond as far as possible to the actual functionality of real elevators. However, due to the miniaturization and the better handling, all control panels and control units are not directly installed inside the model, but separated in a control cabinet.

Because the usage on fairs and exhibitions is possible and welcome, as many components as possible will be provided with windows or will be made of transparent material to allow a better insight. Furthermore, the model will be secured, so that visitors can not touch moving parts or electrical components. To enable the usage on exhibitions, the model will be transportable. This leads to additional demands on the model. The model with dimensions of 1200 mm x 600 mm x 400 mm (HxWxD) is transportable in a car. Furthermore, splitting of the model and securing the movable parts will be guaranteed.

A video of the model you can find at the end of this article.

Control Units and Network

All control units used in the demonstrator should be, as far as possible, original equipment of real CANopen lifts.

The project additionally aims a simulation of the model with all control units with the aid of Vector CANoe and MathWorks Matlab/Simulink. By monitoring the CAN signals of the demonstrator, both programs shall reflect the status of the system. Furthermore, additional control messages should be able to send from these programs to enable a remote control (e.g. call a lift). Thus, additional components or a third shaft may be simulated. In a follow-up project, remote diagnosis is planned.


Gesamtmodell Gesamtmodell


Kabine Kabine mit Führung

Current Status of the Project

Currently, the design of the system is made with CATIA V5 R19 by Dassault Systèmes.

Simultaneously, the Matlab/Simulink and CANoe models are built.

Sponsors

Because some components of the elevator model are very expensive, especially the electronic components, you are kindly invited to contribute with your products. We will attach your logo at a prominent place on the model to indicate you as a sponsor.

The following companies already contribute to the model:

  • Böhnke + Partner GmbH Steuerungssysteme
  • SCHAEFER GmbH
  • SICK AG
  • SafeLine Deutschland GmbH
  • Henning GmbH & Co. KG
  • Murrplastik Systemtechnik GmbH
  • Weidmüller Interface GmbH & Co KG
  • …to be continued with your help….


If you are interested in sponsoring this project, please contact Mr. Meroth at the following address: ansgar.meroth (at) hs-heilbronn.de

Video

In this video you can see the reference lift at work.