Cathode High Voltage - Experts Only » History » Version 10
Cathode High Voltage - Experts Only¶
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- Cathode High Voltage - Experts Only
Changing the Cathode High Voltage¶
To bring up the expert GUI, first kinit. Then
ssh -X -Y ubdaq-prod-ws01.fnal.gov
If that doesn't work, please do
From there, enter:
ssh -X -Y email@example.com
The password is argon!uboonedaq.
python GlassmanHVGUI.py >& logFile_DATE.txt
This will bring up the expert GUI. Before sending a command, enter the present voltage value in the set voltage window.
The values aren't correct in this picture.
Set voltage: PUT PRESENT VALUE INITIALLY!
Set current: 40
HV Enable: 1
Set critical voltage: 70000
Ramp step 1: 36
Ramp step 2: 4
Ramp down step: 36
HV Drift Rack Power Down Procedure¶
- Ensure that the Glassman is at 0 V. One can see this on the front panel. If the power happens to be off, the voltage is 0.
At this point, if a power outage occurs, it is ok from a HV health standpoint. The remaining steps are additions for a more graceful shutdown.
- Turn off the Glassman by pushing the orange on/off button on the front of the supply.
- Turn off the slow controls box by pulling the on/off switch on the front left side of the box down.
- RPS can be turned off from the back of unit in the rack.
Response to a TPC High Voltage Power Supply Trip¶
Stop. If this occurs during ramping, stop. Turn the voltage on the power supply to zero if it is not already there. Turn off power to the supply.
Discuss with experiment leaders.
If it occurs after running for some time, also stop. Turn the voltage to zero volts if it is not already there. Discuss with the experiment leaders and/or spokespersons.
The first question is if there was actually a spark in the cryostat. We have a tripping supply meaning that if we draw above a set current level, e.g. during a significant discharge, the supply's output goes to zero volts. The supply can also go to zero volts due to power glitches in the unit. This is rare and has been seen only once during an electrical storm. The supply can also behave sub-optimally in extreme heat and humid conditions; such conditions should never be seen at LArTF during normal operations. Real sparks have a fast signal, and without the additional current monitoring and scope, we will not see them.
If we assume there was a spark, it is proposed that we first check out the health of the other subsystems.
- Controls group: Notify the controls/cryo group. Ask if they see anything anomalous.
- Electronics: Perform noise runs. Verify that none of the channels are damaged.
- Light Collection: Ask the light collection group to check their read back.
- Laser/Purity monitor: These systems are unlikely to be damaged, but they should verify read back.
- Field cage: Some previous experiments have broken field cage components with high voltage events. MicroBooNE has learned from this and we not only installed more robust resistors, but also varistors for protection. Here, a 5~kV ramp can be performed and the current draw can be measured from the pick off point to check for a change in current draw indicative of a change in resistance due to a broken resistor. Discharges are not favored along the FR4 supports of the TPC.
- HV: The feedthrough is likely not damaged. If there is reason to believe it or the cable is damaged, we have spares.
If all of the systems pass check out, one should consider the length of time the system was at the previous voltage before tripping and how many trips the experiment will accept.
Location of Spares¶
We have spares of all of the contributed HV components.
- Power supply - the PAB.
- Glassman cable - the PAB.
- Filter pot - the PAB.
- Dielectric Sciences cable - the PAB, MTest, the DAB cage.
- Feedthrough - MiniBooNE building. It is in a cylinder. It is labelled.
- Spring tip - the PAB.