Difference between revisions of "HFI cryogenics"

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(Dilution cooler)
(Dilution cooler)
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==Dilution cooler==
 
==Dilution cooler==
  
The HFI dilution cooler cools the bolometers down to 0.1K through  
+
The HFI dilution cooler cools the bolometers down to 0.1 K through  
the dilution of <sup>3</sup>He into <sup>4</sup>He and the intermediate optical plate to 1.4K through Joule-Thomson expansion of the <sup>3</sup>He and <sup>4</sup>He mixture. Two stages of PID regulation are included on the 0.1K stage. The first one (PID1) is at the dilution cold end itself and provides stability on long timescales. When no thermal perturbation is applied to the bolometer plate, the PID1 alone provides the required stability. A passive thermal filter is mounted between the dilution cold end and the bolometer optical plate. It gives a thermal time constant of several hours between these stages. A second regulation system (PID2) is on the bolometer plate, with a similar time constant. The dilution cooler is described in detail in section 2.3.3 of {{PEarly|2|page=7}}.
+
the dilution of <sup>3</sup>He into <sup>4</sup>He and the intermediate optical plate to 1.4 K through Joule-Thomson expansion of the <sup>3</sup>He and <sup>4</sup>He mixture. Two stages of PID regulation are included on the 0.1 K stage. The first one (PID1) is at the dilution cold end itself and provides stability on long timescales. When no thermal perturbation is applied to the bolometer plate, the PID1 alone provides the required stability. A passive thermal filter is mounted between the dilution cold end and the bolometer optical plate. It gives a thermal time constant of several hours between these stages. A second regulation system (PID2) is on the bolometer plate, with a similar time constant. The dilution cooler is described in detail in section 2.3.3 of {{PEarly|2|page=7}}.
  
 
[[Image:HFI_2_4_1_overal_cryo.jpg|thumb|500px|center|Thermal architecture of Planck/HFI]]
 
[[Image:HFI_2_4_1_overal_cryo.jpg|thumb|500px|center|Thermal architecture of Planck/HFI]]
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The dilution was operated with flows set to the minimum available values, providing a total  
 
The dilution was operated with flows set to the minimum available values, providing a total  
 
lifetime of 30.5 months exceeding the nominal lifetime of 16 months by 14.5 months. The  
 
lifetime of 30.5 months exceeding the nominal lifetime of 16 months by 14.5 months. The  
dilution stage was stabilized by the PID1 at a temperature close to 101mK using 20 to 30nW of power. The bolometer plate was stabilized by the PID2 at 102.8mK with about 5nW. The cooling power values were in very good agreement with those obtained during the ground tests and calibration.
+
dilution stage was stabilized by the PID1 at a temperature close to 101 mK using 20 to 30 nW of power. The bolometer plate was stabilized by the PID2 at 102.8 mK with about 5 nW. The cooling power values were in very good agreement with those obtained during the ground tests and calibration.
  
 
[[Image:HFI_2_4_1_100mK_stability.png|thumb|500px|center|100 mK stages temperatures during the mission]]
 
[[Image:HFI_2_4_1_100mK_stability.png|thumb|500px|center|100 mK stages temperatures during the mission]]
  
However, the cosmic particles interactions with the 0.1K stages induced both temperature fluctuations of the 0.1K plates and glitches on the thermometers measurements.
+
However, the cosmic particles interactions with the 0.1 K stage induced both temperature fluctuations of the 0.1K plates and glitches on the thermometer measurements.
  
At very low frequency, below 1mHz, the temperature fluctuations are very well correlated with the high energy particles hit rate, as measured by the on-board Standard Radiation Environment Monitor (SREM). At frequencies in the 10mHz to 1Hz range, single events inducing a global or partial temperature change of the bolometer plate are observed. Decorrelation of the bolometers signal from the thermal fluctuations is described in the [[TOI processing#Thermal template for decorrelation|TOI processing]] section.
+
At very low frequency, below 1 mHz, the temperature fluctuations are very well correlated with the hit rate of high energy particles, as measured by the on-board Standard Radiation Environment Monitor (SREM). At frequencies in the 10 mHz to 1 Hz range, single events inducing a global or partial temperature change of the bolometer plate are observed. Decorrelation of the bolometer signal from the thermal fluctuations is described in the [[TOI processing#Thermal template for decorrelation|TOI processing]] section.
  
 
[[Image:HFI_2_4_1_100mK_srem.png|thumb|500px|center|Correlation between the TC1 hits count of the SREM (protons of energy larger than 20 MeV) and the 100 mK bolometer plate temperature]]
 
[[Image:HFI_2_4_1_100mK_srem.png|thumb|500px|center|Correlation between the TC1 hits count of the SREM (protons of energy larger than 20 MeV) and the 100 mK bolometer plate temperature]]
  
The 1.4K stage is very stable and given the very low coupling coefficients between the 1.4K optical components and the detectors no effect can be measured on the signal. Detailed thermal analysis of the in-flight stability of the  
+
The 1.4 K stage is very stable and given the very low coupling coefficients between the 1.4 K optical components and the detectors no effect can be measured on the signal. Detailed thermal analysis of the in-flight stability of the  
 
dilution cooler can be found in section  
 
dilution cooler can be found in section  
 
5.4 of {{PEarly|2|page=23}}.
 
5.4 of {{PEarly|2|page=23}}.

Revision as of 20:16, 13 March 2013

(F .Pajot)

Dilution cooler[edit]

The HFI dilution cooler cools the bolometers down to 0.1 K through the dilution of 3He into 4He and the intermediate optical plate to 1.4 K through Joule-Thomson expansion of the 3He and 4He mixture. Two stages of PID regulation are included on the 0.1 K stage. The first one (PID1) is at the dilution cold end itself and provides stability on long timescales. When no thermal perturbation is applied to the bolometer plate, the PID1 alone provides the required stability. A passive thermal filter is mounted between the dilution cold end and the bolometer optical plate. It gives a thermal time constant of several hours between these stages. A second regulation system (PID2) is on the bolometer plate, with a similar time constant. The dilution cooler is described in detail in section 2.3.3 of Planck early paper II .

Thermal architecture of Planck/HFI

The dilution was operated with flows set to the minimum available values, providing a total lifetime of 30.5 months exceeding the nominal lifetime of 16 months by 14.5 months. The dilution stage was stabilized by the PID1 at a temperature close to 101 mK using 20 to 30 nW of power. The bolometer plate was stabilized by the PID2 at 102.8 mK with about 5 nW. The cooling power values were in very good agreement with those obtained during the ground tests and calibration.

100 mK stages temperatures during the mission

However, the cosmic particles interactions with the 0.1 K stage induced both temperature fluctuations of the 0.1K plates and glitches on the thermometer measurements.

At very low frequency, below 1 mHz, the temperature fluctuations are very well correlated with the hit rate of high energy particles, as measured by the on-board Standard Radiation Environment Monitor (SREM). At frequencies in the 10 mHz to 1 Hz range, single events inducing a global or partial temperature change of the bolometer plate are observed. Decorrelation of the bolometer signal from the thermal fluctuations is described in the TOI processing section.

Correlation between the TC1 hits count of the SREM (protons of energy larger than 20 MeV) and the 100 mK bolometer plate temperature

The 1.4 K stage is very stable and given the very low coupling coefficients between the 1.4 K optical components and the detectors no effect can be measured on the signal. Detailed thermal analysis of the in-flight stability of the dilution cooler can be found in section 5.4 of Planck early paper II .

1.4K stage temperatures during the mission


4K J-T cooler[edit]

The HFI 4K Joule-Thomson (J-T) cooler produces a temperature of 4K for the HFI 4K stage and optics and the precooling of the dilution gases. Full description of the 4K cooler can be found in in section 2.3.2 of Planck early paper II .

The two mechanical compressors produce micro-vibrations and also induce electromagnetic interference affecting the science signals of bolometers. The risks associated with these effects were taken into account early in the design of the HFI by phase-locking the sample frequency of the data to a harmonic of the compressors frequency. The removal of these interferences is addressed in the 4K cooler lines variability section.

Operation of the 4K J-T cooler was flawless during the whole mission, but for an unexpected shutdown during the CPV on August 6th 2009, caused by an SEU on the precharge regulator. It never occured again, and the 4K J-T cooler was then operated without interruption during all the survey phase of the mission. It is still in operation as it also provides the cooling of the optical reference loads of the LFI.

The 4K J-T cooler compressors amplitude was set to 3450 micrometers during the CPV, and was maintained to this value during all the mission. Its cooling power is very stable and gives enough margin to cancel out the fluctuations and drifts induced by the sorption cooler fluctuations and adjustments. The PID stabilizing the temperature of the HFI optics is regulated at 4.81K using a power around 1.8mW.

Details on the in-flight performance of the 4K J-T cooler can be found in in section 5.3 of Planck early paper II .

4K stage temperatures during the mission


(Planck) High Frequency Instrument

Space Radiation Environment Monitor

Calibration and Performance Verification

(Planck) Low Frequency Instrument