MuCool Absorber Review meeting FermiLab, Chicago 21 – 22 February 2003 Fluid Flow and Convective...
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![Page 1: MuCool Absorber Review meeting FermiLab, Chicago 21 – 22 February 2003 Fluid Flow and Convective Heat Transfer Modelling by Wing Lau & Stephanie Yang Oxford.](https://reader030.fdocuments.us/reader030/viewer/2022032704/56649d4d5503460f94a2be72/html5/thumbnails/1.jpg)
MuCool Absorber Review meeting
FermiLab, Chicago
21 – 22 February 2003
Fluid Flow and Convective Heat Transfer Modelling
by
Wing Lau & Stephanie Yang
Oxford University
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1)
2)
Nozzle sizes are different in each model: Model 1 has nozzle diameter of 0.43”, and Model 2 has 0.63” diameter nozzle opening
Fluid flow / thermal interaction analyses were carried out to see if the nozzle arrangement is sufficient for the cooling requirement.
Further analyses were carried out to see if the flow speed could be reduced to minimise the impact on pressure loss within the cryogenic system while maintaining its cooling capacity
All models are based on a 22cm window size
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The 3-D model
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Model showing the arrangement of the inlet and outlet nozzles
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Model showing detail arrangement of the nozzles
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For the Heat transfer Analysis:
The Beam is represented by a tube of 10mm radius across the absorber centre from one Window to the other.
Beam Power is assumed to be 150W at steady state.
The beam as a fluid sub-domain
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3-D grid of the model
Fluid domain tube to represent the
beam at 150W heating power Nozzle diameter: 0.43”
At 2 m/s inlet speed, it gives a total flow rate of 145 g/sec
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Flow pattern on the combined fluid / heat model – unaffected by the presence of the heat source
Does the presence of the “heater” affect the fluid Flow?
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Flow distribution inside the Absorber
Inlet flow speed: 2m/s
Inlet flow speed: 0.5m/s
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Looking at the flow
pattern from a 2-D plane
Inlet flow speed: 2 m/s
Inlet flow speed: 0.5 m/s
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Traces of all the flow paths from the 11 inlet nozzles
Inlet flow speed: 2 m/s
Inlet flow speed: 0.5 m/s
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Traces of the individual flow paths from each inlet nozzle for the 2m/s flow model
Nozzle 1 Nozzle 2 Nozzle 3 Nozzle 4
Nozzle 5 Nozzle 6 Nozzle 7 Nozzle 8
Nozzle 9Nozzle 10
Nozzle 11
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An aerial view of the temperature distribution in the Absorber
Inlet flow speed: 2 m’s
Max. temp. increase: 0.38K
Inlet flow speed: 0.5 m/s
Max. temp increase: 1.01K
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Cooling of a 150 W beam – red patch shows an area least cooled by the flow
Inlet flow speed: 2 m/s
Max. temp increase: 0.38K
Inlet flow speed: 0.5 m/s
Max. temp increase: 1.01K
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Traces of the individual Flow & Heat paths for the 0.5 m/s flow model
Traces of the flow paths Traces of the heat paths
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Multi-flow Paths and flow pattern of all nozzles
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Multi-flow Paths of all nozzles
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Temperature distribution inside the Absorber
Max. temp increase: 0.15K
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The proposed arrangement of the nozzles seem to provide adequate coverage to both windows;
It is important that the row of inlet nozzles nearest to the window be aiming at centre of that window, and not at the opposite window as the current design implies;
The results show that the Absorber with fewer but larger diameter nozzles seems to provide betting cooling power;
At a low inlet speed of 0.5 m/s, the Absorber with 11 inlet nozzles seems to provide adequate cooling to the 150W beam source. Temperature in the LH2 is only raised by approximately 1 K;
At present we have modelled the beam geometry as a solid tube of 10mm radius. Further analysis is needed to vary the distribution of the beam source to see if it has any effect on the thermal results;
Future analysis will include a metallic window and Absorber body to study the conduction effect. The present model assumes these boundary as an arbitrary adiabatic wall.
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Case 1 study –Convective heat transfer onlyFluid temp: 17KHeater Power: 60WWall temp. 17K constant
Natural Convection pattern
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Case 1 study –Convective heat transfer onlyFluid temp: 17KHeater Power: 60WWall temp. 17K constant
Temperature distribution pattern
Max. temp rises: 0.4K
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Region 3
Region4
Region1
Region 2Inlet nozzle
Outlet nozzle
Top view of the model
Region 1 – flow compartmentRegion 2 – dividing wallRegion 3 – Convective chamberRegion 4 -- Heater
Modelling convective heat transfer with active cooling outside
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The 3-D model of the Convective Absorber
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Case 2 –
Coolant inlet velocity: 1m/sTemp: 4KHeater Power: 60W
Plot showing Coolant flow pattern
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Case 3 –
Coolant inlet velocity: 0.01m/sTemp: 17KHeater Power: 60W
Velocity plot
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Case 3 –Coolant inlet velocity: 0.01m/sTemp: 17KHeater Power: 60W
temp. plots
Global Specified range