Virtual integration platform for computational fluid dynamics

Question

1. What are the contributions mentioned in the paper "Virtual integration platform for computational fluid dynamics" ?

2. What technologies enable distributed designers to access catalogue?

3. What are the main objectives of the multi-objective optimisation case study?

4. What is the purpose of the VIP?

Accepted Answer

In an effort to solve such problems for future CFD computations, a Virtual Integration Platform ( VIP ) has been developed in the University of Strathclyde within two EU FP6 projects – VIRTUE and SAFEDOR.. The VIP provides a holistic collaborative environment for designers with features such as Project/Process Management, Distributed Tools Integration, Global Optimisation, Version Management, and Knowledge Management.. Its main functionalities along with advances are presented in this paper with two industrial applications.

Accepted Answer

Web technologies, such as Java, search engines, XML (eXtensible Markup Language), and RMI (Remote Method Invocation), enable distributed designers to access catalogue, design on components and subassemblies, design tools, and services, and to communicate with other members.

Accepted Answer

The multi-objective optimisation case study carried out in MARIN involved three disciplines of ship hull design: resistance, manoeuvring, and sea keeping.

Accepted Answer

By integrating visualisation tools, such as AMIRA, the VIP enables designers to visualise different types of data, and compare multiple design results from 2D to 4D simultaneously.

Accepted Answer

For the simple one-parameter optimisation demonstrated in this case study, the expert was only needed at the beginning for set-up, and at the end to verify that the requirements had been met.

Accepted Answer

a data translation module was executed from within the VIP and extracted the wake distribution information from the RANSE output, which was saved to the set of “derived data” in the common data model and used by the ppb code.

Accepted Answer

The VIP used in this case study is intuitive for designers to build up projects and processes, integrate tools, and configure inputs and outputs for the tool.

Accepted Answer

Set up the optimisation in optimiser • Run a Design of Experiments Time Savings • Run a formal optimisation4.2 (b) Process in VIPThe multi-objective optimisation process includes three parallel workflows, which consolidate the tools, input and output files, parameters, as well as the transforms between parameters and files.

Accepted Answer

In addition to the management of procedural knowledge, the version management mentioned in Section 3.6 also provides knowledge management mechanism of multiple design solutions, which is declarative knowledge [10].

Accepted Answer

by storing the correct configuration of the tools used in this project in the platform, errors caused by human carelessness were eliminated.

Accepted Answer

Allowing the process to run, autonomously, overnight could evaluate hundreds of design variations over a multiple parameter search field.

Accepted Answer

For this case study, it took only three hours for a first-time user to be familiar with the platform, build up the process and finish configuration.

Accepted Answer

This paper presented a Virtual Integration Platform (VIP) developed in the University of Strathclyde within two EU funded projects – VIRTUE and SAFEDOR, under the FP6 framework.

Accepted Answer

The VIP has facilitated the in-house codes improvement as a direct result of integrating the tool into the platform, which shows that the VIP can also be used for testing CFD/design tools being developed.

Accepted Answer

The main parameters of the vessel and propeller are given in Table 1:Propulsion prediction evaluations are necessary to ensure that the propeller performance matches the predicted engine power or the required thrust at the right RPM.

Accepted Answer

The VIP can manage such procedural knowledge through capturing them in design process templates as configuration knowledge, which can be reused in other processes by same or different designers.

Accepted Answer

The “RESISTANCE prediction” (including thrust deduction) is the target thrust value that the propeller should produce (within reasonable margin).

Accepted Answer

it would enhance design efficiency for the VIP to have the data mining function, so that results related with particular versions of parameters can be searched and explored across organisation(s).

Virtual integration platform for computational fluid dynamics

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Most frequently asked questions

1. What are the contributions mentioned in the paper "Virtual integration platform for computational fluid dynamics" ?

2. What technologies enable distributed designers to access catalogue?

3. What are the main objectives of the multi-objective optimisation case study?

4. What is the purpose of the VIP?

5. What was the role of the expert in the case study?

6. What is the purpose of the wake distribution in the VIP?

7. What is the main purpose of the VIP?

8. What is the purpose of the optimisation in VIP?

9. What is the main advantage of the version management?

10. How many errors were eliminated by the VIP?

11. How many design variations could be evaluated?

12. How long did it take for a first time user to be familiar with the platform?

13. What is the purpose of the paper?

14. What is the role of the VIP in the design of ships?

15. What are the main parameters of the vessel and propeller?

16. What is the advantage of the VIP?

17. What is the thrust value of the propeller?

18. What is the benefit of having the data mining function in the VIP?

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Citations

Modes of integrated collaborative ship design

References

Agile Software Development with SCRUM

Agile software development with Scrum

Agent-based collaborative product design engineering: an industrial case study

Design Support Using Distributed Web-Based AI Tools

The Design Research Pyramid: A Three Layer Framework

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