H. Dinwiddie NRAO-EVLA1 X-Band OMT Evaluation SOC Design Thermal Analysis 2009/10/01.

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Presentation transcript:

H. Dinwiddie NRAO-EVLA1 X-Band OMT Evaluation SOC Design Thermal Analysis 2009/10/01

Approach Finite Element Analysis –Have the tools (CFDesign) –No verified models –Learning curve –Limited time Simplified Approach –Treat the complex surfaces as cylinders and plates –Only evaluate critical areas ( large surface areas with large temperature differences) –Evaluate for the worst case thermal conductivity and emissivity –Calculate all of the 300K to 50K and 50K to 15K loads –Compare with the cold head capabilities H. Dinwiddie NRAO-EVLA2

First Stage Loads H. Dinwiddie NRAO-EVLA3

Second Stage Loads H. Dinwiddie NRAO-EVLA4

Approximate Total Loading First Stage:21.1W Second Stage:0.75W –Assuming 100K Shield Compare with CTI Performance Chart H. Dinwiddie NRAO-EVLA5

CTI Model 22 H. Dinwiddie NRAO-EVLA6

Evaluations The loads are within the range of the second stage To get the OMT below 20K the first stage needs to be around 100K –Previous second stage load was calculated from a 100K second stage At least 10W off the chart on the first stage –Add radiation blankets (floating shields) to provide protection from the 300K environment H. Dinwiddie NRAO-EVLA7

Floating Shields The use of independently floating, cascading shields should provide a reduction of transferred power by a factor of N+1 Use of a 4 layer radiation blanket should gives an 80% reduction in transferred power Reduces the load on the first stage to 5.4W H. Dinwiddie NRAO-EVLA8

CTI Model 22 H. Dinwiddie NRAO-EVLA9

Further Reductions Note that top of the thermal gap (15K) is exposed to the 300K Adding some shielding here could also help the load on the second stage Use of a quasi floating gap (tied to the first stage) transfers 99% of the load (0.11W) off of the second stage and onto the first. H. Dinwiddie NRAO-EVLA10

Cool Down H. Dinwiddie NRAO-EVLA11

Cool Down Numbers H. Dinwiddie NRAO-EVLA12

Success? Within the target range of 20K on the second stage But no heat load from the stainless coaxial cables and amplifiers Next Step –Apply a 50mW load thru the heating resisters to simulate the electronic heat load –Miscommunication and applied a 2W heat load H. Dinwiddie NRAO-EVLA13

2W Load Chart H. Dinwiddie NRAO-EVLA14

2W Load Numbers H. Dinwiddie NRAO-EVLA15

No Such Thing As Bad Data Extremely long cool down time: 33hrs Failed to reach the 20K target range: 25K Floating gap settled at 220K Second Stage over loaded by 400 times Next Step –Apply a 50mW load thru the heating resisters to simulate the electronic heat load H. Dinwiddie NRAO-EVLA16

50 mW Load Chart H. Dinwiddie NRAO-EVLA17

50 mW Load Notes Cool down time*: 17hrs Within the 20K target range Not an official cool down, unstable starting points The CTI Model 22 can handle the electronics heat load H. Dinwiddie NRAO-EVLA18

Future Work Reduce the resistance between the first stage shields be adding thermal strapping Reduce the 300K effects through the waveguide by adding a foam plug into the floating gap Reduce the size of the dewar and radiation shields H. Dinwiddie NRAO-EVLA19

Conclusion The proposed X-Band Quad-Ridge OMT is capable of being cooled with a CTI Model 22 in the 20K range. Cool down time in the current configuration are approximately18hrs. Appears to be room for improvement H. Dinwiddie NRAO-EVLA20

Questions H. Dinwiddie NRAO-EVLA21