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Detailed Design P13601

Detailed Design P13601. Bill Dullea , Garry Clarke, Jae Ho, Kelly McNabb, Mary Medino. Process Flow Diagram. Process & Instrumentation Diagram . Process & Instrumentation Diagram . Process & Instrumentation Diagram . Process & Instrumentation Diagram . Process & Instrumentation Diagram .

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Detailed Design P13601

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  1. Detailed DesignP13601 Bill Dullea, Garry Clarke, Jae Ho, Kelly McNabb, Mary Medino

  2. Process Flow Diagram

  3. Process & Instrumentation Diagram

  4. Process & Instrumentation Diagram

  5. Process & Instrumentation Diagram

  6. Process & Instrumentation Diagram

  7. Process & Instrumentation Diagram

  8. Current Specifications: Chiller

  9. Labview Interface Design

  10. Current Specifications: Beaker

  11. Heat Transfer Equations • Illustrates the sample set taken from previous tests to provide a peak current and a steady-state current

  12. Heat Transfer Equations • Illustrates the dimensions of the Polypropylene Beaker • The area of heat transfer is dependent on the amount of solution that is within the beaker • There are three different volumes of solution provided to give a range of results

  13. Heat Transfer Equations • Utilizing the elemental properties values, the Overall Heat Transfer Coefficient. [Reference] Forced Convection of water http://www.engineeringtoolbox.com/convective-heat-transfer-d_430.html Thermal Conductivity http://www.engineeringtoolbox.com/thermal-conductivity-liquids-d_1260.html

  14. Heat Transfer Feasibility • Table 5 illustrates the Heat Generated from the electrodes • Applied an average of peak and steady state current use • Ultimately calculate the • temperature difference from Solution to coolant, to see how effective the water bath system is at cooling.

  15. Heat Transfer Feasibility • Initial Temperature of solution was 65 Deg C • Temperature was calculated with the Heat Transfer Equation (Previous Slide) • Table 6 • Heat Generated from the electrodes • Average steady state current • Calculated the T of the coolant • Table 7 • Heat Generated from the electrodes • average peak current; • calculated the T of the coolant

  16. Heat Transfer Feasibility • Table 8 illustrates the time required for the chiller to change the coolant temperature by 1 degree. • Table 9 illustrates the time required for the chiller to translate from the peak heat generated to the steady state heat generated. • These results provide vital information on what needs to be done with labview.

  17. Test Plans

  18. Risk Assessment

  19. Bill of Materials

  20. Questions, Comments, Concerns?? Why are we doing this? What problem are we solving? Is this actually useful? Is there an easier way? What’s the opportunity cost? Are we on our critical path? Is it really worth it?

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