E. Da Riva/M. Gomez Marzoa1 WG4 Meeting - 27th June 2012 Air Cooling by means of carbon fiber structure Enrico DA RIVA (EN-CV-PJ) Manuel GOMEZ MARZOA (EN-CV-PJ) 27 th June 2012
E. Da Riva/M. Gomez Marzoa2 WG4 Meeting - 27th June 2012 Outline Air cooling: unites cooling performance and material budget. Triangular carbon fiber structure considered, using it for cooling. Similar solution as the STAR experiment: 8 m s -1, 0.1 W cm -2 Advantages: Simple cooling system No extra material added Disadvantages: Adequate for low power densities Restricted air velocity (vibrations) Sensor temperature uniformity STAR Experiment Models studied by means of CFD: 1.Single stave: Thermal fin performance 2.A two-layer model of the ITS Barrel
E. Da Riva/M. Gomez Marzoa3 WG4 Meeting - 27th June 2012 Overview Single stave: Thermal fin performance Geometrical features: CF: 130 µm thick Si: 50 µm thick Stave: 300 mm long Material properties: CF: k = 620 W m -1 K -1 (assumed to be isotropic) Si: k = 150 W m -1 K -1 Boundary conditions: T air Inlet = 14 °C v Inlet q’ Silicon IN OUT Si sensor 268 mm 15 mm
E. Da Riva/M. Gomez Marzoa4 WG4 Meeting - 27th June 2012 Single stave: CFD Analysis 0.3 W cm -2, 10 m s -1 Temperature CF [°C] Temperature silicon [°C] T max = 60 °C
E. Da Riva/M. Gomez Marzoa5 WG4 Meeting - 27th June W cm -2, 20 m s -1 Single stave: CFD Analysis Temperature sensor [°C] Temperature stave [°C] T max = 43 °C
E. Da Riva/M. Gomez Marzoa6 WG4 Meeting - 27th June 2012 Stave heat flux [W m -2 ] q’ = 0.3 W cm -2, 10 m s -1 Single stave: conclusions Only the case with 0.1 W cm -2 and 10 m s -1 would fulfill the detector thermal requirements for a single stave The behaviour of the stave as a thermal fin is seen Thermal performance improved when cooling from both sides of the triangular shape. 0.1 W cm -2, 10 m s -1 T max = 30 °C
E. Da Riva/M. Gomez Marzoa7 WG4 Meeting - 27th June A two-layer model of the ITS Barrel: Only a section including two triangular shapes was modeled Assumed a 30 mm chamber at the barrel end as recirculation zone Mesh: ~ 5 million cells Turbulence model: SST k-ω, Low-Re corrections 30 mm L1 L2 Beam Pipe Two-layer model: description
E. Da Riva/M. Gomez Marzoa8 WG4 Meeting - 27th June 2012 Two-layer model: description Sector of the ITS barrel was modeled by means of CFD Two inlet ducts and one outlet per layer Simplified geometry built from the mechanical CAD design Total length stave: 300 mm (268 mm sensor) + recirculation region Material properties: CF: o T300 fabric (biaxial thermal conductivity) k Planar = 400 W m -1 K -1 k Transv = 1.2 W m -1 K -1 o Thickness: 130 µm (triangles and separation layers) Si: k = 150 W m -1 K -1 Boundary conditions: v Inlet = 10 m s -1 q’ Sensor = 0.3 W cm -2 T air Inlet = 14 °C
E. Da Riva/M. Gomez Marzoa9 WG4 Meeting - 27th June 2012 Two-layer model: CFD study 0.3 W cm -2, 10 m s -1 Magnitude of air velocity in a plane along the volume [m s -1 ] Pressure drop: L1 = 325 Pa, L2 = Pa
E. Da Riva/M. Gomez Marzoa10 WG4 Meeting - 27th June 2012 Two-layer model: CFD study 0.3 W cm -2, 10 m s -1 Temperature silicon L1 [°C] Temperature silicon L2 [°C]
E. Da Riva/M. Gomez Marzoa11 WG4 Meeting - 27th June 2012 Two-layer model: CFD study 0.3 W cm -2, 10 m s -1 Heat flux silicon in triangle L2 [W/m2]Heat flux to outlet L2 [W/m2]
E. Da Riva/M. Gomez Marzoa12 WG4 Meeting - 27th June 2012 Two-layer model: CFD study 0.3 W cm -2, 10 m s -1 Temperature CF stave L1 [ °C ]
E. Da Riva/M. Gomez Marzoa13 WG4 Meeting - 27th June 2012 Outcome The silicon is only cooled with the air flow inside the triangular duct, because v outlet duct is small. Possible solutions: 1.Increase air velocity Vibration & shear stress increase 2.Equalize inlet/outlet sections: guarantee high velocity at outlet ducts 3.Use different cooling fluid Laminar flow and small molecule: no stresses over mechanical structure Still, cooling from both sides of the sensor has to be guaranteed Umean [m s -1 ]1020 Re FlowTransitionalTurbulent Umean [m s -1 ] Re FlowLaminar AIR HELIUM
E. Da Riva/M. Gomez Marzoa14 WG4 Meeting - 27th June 2012 Outcome The silicon is only cooled with the air flow inside the triangular duct, because v outlet duct is small. Possible solutions: 1.Increase air velocity Vibration & shear stress increase 2.Equalize inlet/outlet sections: guarantee high velocity at outlet ducts 3.Use different cooling fluid Laminar flow and small molecule: no stresses over mechanical structure Still, cooling from both sides of the sensor has to be guaranteed Solution to be used for low q’ Umean [m s -1 ]1020 Re FlowTransitionalTurbulent Umean [m s -1 ] Re FlowLaminar AIR HELIUM
E. Da Riva/M. Gomez Marzoa15 WG4 Meeting - 27th June 2012 Enrico DA RIVA (EN-CV-PJ) Manuel GOMEZ MARZOA (EN-CV-PJ) 27 th June 2012 Air Cooling by means of carbon fiber structure