Difference between revisions of "The leaky tank mystery 2024"
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of the deflection. | of the deflection. | ||
| − | ==Specific | + | ==Specific Tasks== |
| − | + | The project will be completed via the completion of two primary tasks/objectives which consist of multiple sub-tasks. The primary tasks include: | |
| − | |||
| − | + | Theoretical and Simulation Analysis: | |
| − | * | + | * Perform an analysis of all parameters that affect the motion of the tank, to determine the optimal parameters to maximise movement |
| + | |||
| + | * Use of multiphysics simulation softwares such as COMSOL to model and optimise the leaky tank | ||
| + | |||
| + | |||
| + | Experimental Validation: | ||
| + | |||
| + | * Build a physical version of the tank | ||
| + | |||
| + | * Complete testing to observe the motion of the leaky tank based on different variables | ||
| + | |||
| + | * Analysis of these results | ||
==Deliverables== | ==Deliverables== | ||
===Semester 1=== | ===Semester 1=== | ||
| − | |||
* Proposal seminar | * Proposal seminar | ||
| + | ** [[File:The Leaky Tank Mystery - Seminar Slides.pdf]] | ||
* Progress report | * Progress report | ||
** [[File:Progress Report - Leaky Tank.pdf]] | ** [[File:Progress Report - Leaky Tank.pdf]] | ||
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== Weekly progress and questions == | == Weekly progress and questions == | ||
Weekly progress and questions were recorded in our minutes. | Weekly progress and questions were recorded in our minutes. | ||
| − | *[[File:The Leaky Tank Mystery - Meeting Minutes.zip | + | *[[File:The Leaky Tank Mystery - Meeting Minutes.zip]] |
==Approach and methodology== | ==Approach and methodology== | ||
| − | + | Through use of COMSOL and simulative software a set of optimal dimensions for a physical tank can be designed. Using these dimensions a physical model of the tank can be built. This physical model can then be used in experimental testing to observe and analyse the motion of the leaky tank. | |
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== Relationship to possible career path== | == Relationship to possible career path== | ||
| − | The skills | + | The skills learnt from simulating, experimenting, and project managing this problem will be relevant to a wide range of engineering careers, as well as various aspects of fluid mechanics and understanding the behaviour of fluid. |
== References and useful resources== | == References and useful resources== | ||
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* [http://kirkmcd.princeton.edu/examples/tankcar.pdf Motion of a leaky tank] | * [http://kirkmcd.princeton.edu/examples/tankcar.pdf Motion of a leaky tank] | ||
* [http://kirkmcd.princeton.edu/examples/haldane.pdf Haldane's cart] | * [http://kirkmcd.princeton.edu/examples/haldane.pdf Haldane's cart] | ||
| + | * [[File:The physical leaky tank car problem revisited .pdf]] | ||
| + | * [[File:Two toy models of the leaky tank car.pdf]] | ||
==Back== | ==Back== | ||
Latest revision as of 01:23, 8 November 2024
Contents
Supervisors
Honours students
Project guidelines
General project description
Imagine one of those railcars that has a big horizontal water tank. Pretend it is frictionless. Imagine the tank is full. Imaging there's a hole at the top to let air in. Imagine the tank is leaking through a small hole on the left bottom side of the tank. Assume the jet of water is vertically downward. Does the resulting change in momentum push the railcar to the left or the right?
This is a very famous problem that has never been properly solved. We need finally put it to rest. We will give you papers showing attempted solutions that contradict each other. You may try to search for more papers on the topic.
The experiment is almost impossible to do in practice as the forces are smaller than the friction you get in real life. This explains why there are contradictory solutions. This illustrates an important principle in engineering that your can never be sure of the theory until you do the experiment.
But the modern world of engineering now has simulation tools that we trust and are as good as an experiment provided we don't feed it with wild parameters outside of the range that models are valid.
We want you to do the "experiment" in simulation using Comsol and/or Ansys. The Faculty has licences. Find the answer. Then go and find which theory paper got it correct. Then nicely explain that theory yourself, written out clearly in your own way.
This is a beautiful classic problem and it will be a lot of fun. If you can think of a clever way to actually do a low friction experiment and video it, this will be a cherry on that cake and your name will go down in history. Suggest you design a rectangular tank and suspend it hanging with four cords attached to the corners. You'll need to design a release valve for the water that is actuated by a remote (because you can't touch the tank). Suggest you bounce a laser pointer off the tank as a way of measuring deflection. However, you need to fully simulate the tank first to get all the size parameters right to optimize the size of the deflection.
Specific Tasks
The project will be completed via the completion of two primary tasks/objectives which consist of multiple sub-tasks. The primary tasks include:
Theoretical and Simulation Analysis:
- Perform an analysis of all parameters that affect the motion of the tank, to determine the optimal parameters to maximise movement
- Use of multiphysics simulation softwares such as COMSOL to model and optimise the leaky tank
Experimental Validation:
- Build a physical version of the tank
- Complete testing to observe the motion of the leaky tank based on different variables
- Analysis of these results
Deliverables
Semester 1
- Proposal seminar
- Progress report
Semester 2
- Ingenuity Poster
- Ingenuity Video
- Final Report
Weekly progress and questions
Weekly progress and questions were recorded in our minutes.
Approach and methodology
Through use of COMSOL and simulative software a set of optimal dimensions for a physical tank can be designed. Using these dimensions a physical model of the tank can be built. This physical model can then be used in experimental testing to observe and analyse the motion of the leaky tank.
Relationship to possible career path
The skills learnt from simulating, experimenting, and project managing this problem will be relevant to a wide range of engineering careers, as well as various aspects of fluid mechanics and understanding the behaviour of fluid.
References and useful resources
If you find any useful external links, list them here:
- Motion of a leaky tank
- Haldane's cart
- File:The physical leaky tank car problem revisited .pdf
- File:Two toy models of the leaky tank car.pdf
