Difference between revisions of "Assignment 2 - 2012"

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| questions_PDF = 4M3-2012-Assignment-2.pdf
| questions_PDF = 4M3-2012-Assignment-2.pdf
| questions_text_alt = Assignment questions
| questions_text_alt = Assignment questions
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| questions_link =
| solutions_PDF = 4M3-2012-Assignment-2-Solutions.pdf
| solutions_text_alt = Assignment solutions
| solutions_text_alt = Assignment solutions
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.. question::
.. question::


A rectangular settling basin is used for clarifying a mixed water-biomass stream at a feed rate of 130 :math:`\text{m}^3` per hour. The basin area is 5000 :math:`\text{m}^{2}`,.  
A rectangular settling basin is used for clarifying a mixed water-biomass stream at a feed rate of 130 :math:`\text{m}^3` per hour. The basin area is 5000 :math:`\text{m}^{2}`.  
There are biomass particles with approximately the following sizes present: 5\ |micron|, 8\ |micron|, 12\ |micron| and 20\ |micron| and these particles have a density of 1100\ :math:`\text{kg.m}^{-3}`.
There are biomass particles with approximately the following sizes present: 5\ |micron|, 8\ |micron|, 12\ |micron| and 20\ |micron| and these particles have a density of 1100\ :math:`\text{kg.m}^{-3}`.
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.. question::
.. question::


A flocculant test on laboratory samples appears to quadruple the settling time from 0.5\ :math:`\text{mm.s}^{-1}` to almost 2\ :math:`\text{mm.s}^{-1}` for a given waste stream. What is the effect on the tank diameter, and the approximate effect on the capital cost?
We are designing a new sedimentation unit. A flocculant test on laboratory samples appears to quadruple the settling time from 0.5\ :math:`\text{mm.s}^{-1}` to almost 2\ :math:`\text{mm.s}^{-1}` for a given waste stream. What is the effect on the design's tank diameter, and the approximate effect on the capital cost?


.. question::
.. question::
The current thickener you are operating needs to handle a feed increase of 180\ :math:`\text{m}^3\text{hr}^{-1}` to 225\ :math:`\text{m}^3\text{hr}^{-1}`. It is the last step before discharging the overflow stream to municipal treatment. Since your company is under investigation from government authorities already, there can be absolutely no risk of discharging additional solids in the overflow.
A thickener is operating at the designed feed rate of 180\ :math:`\text{m}^3\text{hr}^{-1}` but needs to be operated at 225\ :math:`\text{m}^3\text{hr}^{-1}` due to increased upstream production. It is the last step before discharging the overflow stream to municipal treatment. Since your company is under investigation from government authorities already, there can be absolutely no risk of discharging additional solids in the overflow.
Clearly explain at least 3 options you can realistically investigate to handle the increased flow; and be as creative as possible. Also, be clear on the expected magnitude of your effect: is it linear or some other function?
Clearly explain at least 3 options you can realistically investigate to handle the increased flow; and be as creative as possible. Also, be clear on the expected magnitude of your effect: is it linear or some other function?
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.. question::
.. question::


It is required to settle dust particles from a moving air stream. One option that could be used to pipe the incoming dust/air mixture to a large rectangular container with a dissipator. A moving conveyor belt on the bottom of the container will remove any solid particles that settle out of the air. The clean(er) air can be withdrawn from the other side of the container. Your company is trying to do this as cheaply as possible, so they are using a `standard shipping container <http://www.srinternational.com/standard_containers.htm>`.  
It is required to settle dust particles from a moving air stream. One option that could be used is to pipe the incoming dust/air mixture to a large rectangular container with a dissipator at the container entrance. A moving conveyor belt on the bottom of the container will remove any solid particles that settle out of the air. The clean(er) air can be withdrawn from the other side of the container. Your company is trying to do this as cheaply as possible, so they are using a `standard shipping container <http://www.srinternational.com/standard_containers.htm>`_.  
The particles have density of 1300\ :math:`\text{kg.m}^{-3}`. Pick a container size and calculate the minimum theoretical particle size that will drop out. Apply an overdesign factor of 10 to the settling velocity.
The particles have density of 1300\ :math:`\text{kg.m}^{-3}`. Pick a container size and calculate the minimum theoretical particle size that will drop out. Apply an overdesign factor of 10 to the settling velocity.


.. question::
.. question::
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Would a cyclone have been an better option for the previous question? Please explain.
Would a cyclone have been an better option for the previous question? Please explain.


.. raw:: latex
.. raw:: latex

Latest revision as of 21:04, 11 November 2012

Due date(s): 25 September 2012
Nuvola mimetypes pdf.png (PDF) Assignment questions
Nuvola mimetypes pdf.png (PDF) Assignment solutions

<rst> <rst-options: 'toc' = False/> <rst-options: 'reset-figures' = False/>

Assignment objectives

=========

Wrapping up the sedimentation section; dealing with more open-ended questions and moving on to other solid-fluid separation systems.

.. |micron| replace:: :math:`\mu \text{m}`

.. question::

A rectangular settling basin is used for clarifying a mixed water-biomass stream at a feed rate of 130 :math:`\text{m}^3` per hour. The basin area is 5000 :math:`\text{m}^{2}`.

There are biomass particles with approximately the following sizes present: 5\ |micron|, 8\ |micron|, 12\ |micron| and 20\ |micron| and these particles have a density of 1100\ :math:`\text{kg.m}^{-3}`.

#. Which particle sizes will be completely separated out? #. What will happen with the other particle sizes?

.. question::

We are designing a new sedimentation unit. A flocculant test on laboratory samples appears to quadruple the settling time from 0.5\ :math:`\text{mm.s}^{-1}` to almost 2\ :math:`\text{mm.s}^{-1}` for a given waste stream. What is the effect on the design's tank diameter, and the approximate effect on the capital cost?

.. question::

A thickener is operating at the designed feed rate of 180\ :math:`\text{m}^3\text{hr}^{-1}` but needs to be operated at 225\ :math:`\text{m}^3\text{hr}^{-1}` due to increased upstream production. It is the last step before discharging the overflow stream to municipal treatment. Since your company is under investigation from government authorities already, there can be absolutely no risk of discharging additional solids in the overflow.

Clearly explain at least 3 options you can realistically investigate to handle the increased flow; and be as creative as possible. Also, be clear on the expected magnitude of your effect: is it linear or some other function?

.. question::

It is required to settle dust particles from a moving air stream. One option that could be used is to pipe the incoming dust/air mixture to a large rectangular container with a dissipator at the container entrance. A moving conveyor belt on the bottom of the container will remove any solid particles that settle out of the air. The clean(er) air can be withdrawn from the other side of the container. Your company is trying to do this as cheaply as possible, so they are using a `standard shipping container <http://www.srinternational.com/standard_containers.htm>`_.

The particles have density of 1300\ :math:`\text{kg.m}^{-3}`. Pick a container size and calculate the minimum theoretical particle size that will drop out. Apply an overdesign factor of 10 to the settling velocity.

.. question::

Provide 3 examples where cyclones are used in industrial practice. Please cite your references for this question.

Would a cyclone have been an better option for the previous question? Please explain.


.. raw:: latex

\vspace{0.3cm} \hrule \center{END}

</rst>