Anders Mjos wrote:

Plant Services group (Tony) will contact a service tech on Monday. Water system will be switched off over the weekend.

Thursday, July 14, 2016, 13:24: Claus from Daikin is on site to troubleshoot.

The VFD driven fan motor has failed. Temporarily blocked air-flow through failed fan to improve air-flow to radiator. A new motor will be ordered (Curtis).

Thursday, July 14, 2016, 15:39: Stopped cooling system for the day

Friday, July 15, 2016, 08:16: Cooling system started

Friday, July 15, 2016, 15:00; Cooling system stopped.

Last Friday July-15, TM3 was leak checked at TCS. All air to vacuum seals on service cap are good.  Helium pressure test on  TM3 water lines(except GE, HS, and Window) were done. Leak detector has no response at 0.0xE-9 atm.cc/sec. They are leak free.

David Wang wrote:

Last Friday July-15, TM3 was leak checked at TCS. All air to vacuum seals on service cap are good.  Helium pressure test on  TM3 water lines(except GE, HS, and Window) were done. Leak detector has no response at 0.0xE-9 atm.cc/sec. They are leak free.

Friday July 15: did HV tests (with no target installed and with the anode wire removed ). <br>

TM3 went up to 22.5kV. At this voltage it started sparking. The EL was kept at 1/2 with respect to the HV BIAS. <br>

Also HV tests were done while the EL was kept at zero V. In this case, the EL voltage was once in a while spiking  up (up to 4kV). <br>

During sparking we saw responses in the vacuum. Checked the Service Cap (with the HV Cover) in the Target Hall: we couldn't hear/see sparks there.  <br>

The HV was turned off in the same day, after 5:30pm.

I started vacuum system.

I started TCS water system. The chiller does not work properly still. But, It will not affect the TM3 HV conditioning.  HV cover is installed on TM3 in TH. The module is ready for HV conditioning.

 Monday, July 25, 2016, 08:14: Enabled staging for chiller

Monday, July 25, 2016, 08:33: Disabled staging. Fault 2. Staging does not work at this point.

Monday, July 25, 2016, 08:34: Running CP1 manually to cool down water.

Monday, July 25, 2016, 09:15: Bias current limiting at 150 V. Investigating short.

Monday, July 25, 2016, 09:51: EE cable was shorting the BIAS on the TCS side.

Monday, July 25, 2016, 09:57: BIAS/ / EL at 20 / 10 kV

Monday, July 25, 2016, 10:08: Sparking at 24 kV. Lowered to 22 kV

Monday, July 25, 2016, 10:44: BIAS at 25 kV

 Monday, July 25, 2016, 11:00: Sparking at 25.5 kV. Lowered to 25 kV

Monday, July 25, 2016, 12:03: 25.5 kV. No sparking for 10 min. Lower to 20 kV for lunch break.

Monday, July 25, 2016, 12:51: 26 kV

Monday, July 25, 2016, 13:00: Sparking at 27.3 kV. Lowered to 27 kV. EL at 14 kV

Monday, July 25, 2016, 13:04: More sparking. Lowered to 25 kV

Monday, July 25, 2016, 13:39: 25 kV

Monday, July 25, 2016, 14:21: A spark tripped the PS on water resistivity

Monday, July 25, 2016, 14:31: 25 kV

Monday, July 25, 2016, 15:34: ~20 sparks for the last 60 min

Monday, July 25, 2016, 16:28: ~10 sparks for the last 60 min. BIAS an EL off

Monday, July 25, 2016, 16:36: Stopped water cooling system.

Tuesday, July 26, 2016, 08:20: Started water cooling system.

Tuesday, July 26, 2016, 08:24: Ran CP1 manually for 3 min. Enabled staging.

Tuesday, July 26, 2016, 08:31: BIAS / EL at 25 / 0 kV

Tuesday, July 26, 2016, 08:39: EL float to 300 V. Set to 500 V

Tuesday, July 26, 2016, 08:45: BIAS to 25.5 kV

Tuesday, July 26, 2016, 09:07: 26 kV

Tuesday, July 26, 2016, 09:12: Lost contact with EPICS. Scheduled maintenance

Tuesday, July 26, 2016, 10:26: 6 sparks for the last 60 min

Tuesday, July 26, 2016, 10:33: BIAS to 27 kV

Tuesday, July 26, 2016, 10:43: Sparking at 27.8 kV. Lowered to 23 kV

Tuesday, July 26, 2016, 10:51: BIAS back at 27 kV. A spark tripped the BIAS on water resistivity

Tuesday, July 26, 2016, 11:08: BIAS at 27 kV

Tuesday, July 26, 2016, 11:22: BIAS at 28 kV

Tuesday, July 26, 2016, 11:42: BIAS at 27 kV after trip due to water resistivity (spark)

Tuesday, July 26, 2016, 12:00: BIAS / EL off for lunch break

Tuesday, July 26, 2016, 14:10: EL to 10 kV

Tuesday, July 26, 2016, 14:14: El to 20 kV

Tuesday, July 26, 2016, 14:20: EL to 25 kV

Tuesday, July 26, 2016, 14:27: First spark at 27.6 kV

Tuesday, July 26, 2016, 14:29: EL to 28 kV (BIAS at 0 kV)

Tuesday, July 26, 2016, 14:43: RGA on

Tuesday, July 26, 2016, 14:49: No sparking for 20 min

Tuesday, July 26, 2016, 16:02: No sparks for 90 min.

Tuesday, July 26, 2016, 16:06: PS and water off.

Wednesday, July 27, 2016, 09:14: BIAS at 24 kV

Wednesday, July 27, 2016, 09:19: Lowered to 20 kV due to sparking

Wednesday, July 27, 2016, 09:28: BIAS at 22 kV

Wednesday, July 27, 2016, 15:30: BIAS and water off

Thursday, July 28, 2016, 08:43: RGA off

The two 45 gal (m) drums of waste removed from the south hot cell in December 2015 and January 2016 were transferred from the north hot cell to the shaft of the east vault tunnel on Monday, July 25th 2016 and subsequently to the east tunnel bunker in the vault tunnel on Tuesday, July 26th, 2016.The first drum (removed from the hot cell in December) containing both activated and contaminated metals was measured at 900 uSv/hr @ .5 m and the second drum (removed from the hot cell in January 2016) containing compressible items such as tank suits and plastic was measured at 150 uSv/hr @ .5 m.

Items were filed for storage/disposal with RPG under item number 1395 on the radioactive storage form.

Drums were transported to the vault tunnel using the 500 Mev Shield Flask (Drawing E-7097) with some minor modifications, namely a 1/4" thick Aluminum plate with four holes that line up with the holes in the bottom flange of the flask. This plate provided a bottom for the flask so that a drum could be contained within the flask during craning. Holes in the plate where countersunk for a 1/2" flat head bolt. Four bolts were also modified to accept 3/16 hair pins. 3 plates with clearances holes for the bolts were also manufactured to act as washers.

Procedure was as follows: With plate, washers and pins installed onto the flask, a modified drum dolly (5" spacers added to the casters) was placed inside the flask. Drum was craned into the flask using the automatic drum lifter. Flask with drum loaded was moved to the Meson Hall loading bay then craned to the B2 level of the Meson hall. Hair pins were pulled from the flask and the flask was then craned up leaving the drum (which was on the dolly firstly installed into the flask) and the plate. Drum on dolly was rolled to vault access shaft where it was craned off the modified dolly using the automatic drum lifter and down the access shaft to the vault tunnel level.  A second drum dolly was waiting at the bottom level and drum lowered onto it. Procedure was repeated for the second drum

Was vault was open , drums were wheeled into the vault tunnel and into a bunker that had been modified to accept these drums. Drums were lifted off dollies and put in place in bunker which had blocks installed to cover the entrance provided for installation.

Pictures can be found on docushare http://documents.triumf.ca/docushare/dsweb/View/Collection-18072  (collection 18072)

 The North Hot Cell was accessed today via the Ante Room for inspection, measurements, and clean-up.  There were no modules in the SHC or TCS, and no spent targets in the SHC.  Under these conditions the maximum field in the NHC was approximately 2μSv/hr.  The inside of the cell was cleaned and swept, followed by a floor swipe to check for contamination (none found).  All areas of the ante room floor were also swiped:  no contamination found.

The following measurements were taken in the NHC for comparison with the Soldiworks model:

SHC/NHC feedthrough panel fastener size:  1/4"-20,  1/2" long
NHC west wall to east edge of SEG block:  33-1/4" on south side, 33" on north side
NHC west wall to furthest extent of TCS (IRH1170): 40"
NHC west wall to wall indentation for viewing window: 46-7/8"
NHC west wall to end of existing ventilation duct: 4-1/8"

East manipulator on the south hot cell is showing signs of eminent wrist/tong cable failure. Some slight slippage was noted yesterday and confirmed by a snapping sound and more slippage tomorrow.

I started TCS water system and installed HV cover onto TM4.  The TM4 containment box is supplied with water also. TM4 is ready for conditioning at TCS.

Update schedule weekly. See attachments 1,2

Some items have been removed from the anteroom in preparation for painting. Items have been placed on plastic in the south hot cell service area. No contamination found so far.

A hole was drilled in the NHC exhaust duct in the east end of the target hall above the hatch to the Ante Room.  This will be used for measuring NHC exhaust flow rate with a thermal anemometer.  The hole was tapped and plugged with an NPT tap.

Flow was measured in the existing hole in the SHC exhaust duct in approximately the same location.  Flow velocity was measured to be 1415 ft/min with the lid on the SHC.  Using duct ID 7.75", and assuming the average flow velocity is 90% of the flow at duct center, the flow rate was found to be 417cfm.  We will attempt to match this figure for the NHC when the ventilation tests are performed.  The tests have been scheduled for the maintenance day on Tuesday August 9th.

The anemometer probe and SHC test port plug were checked for contamination: none found.

The wave guide from TM3 has been surveyed, swiped and removed from the anteroom and transported to rad waste for disposal. The wave guide has been stored in the anteroom since its removal.

 The locations (ports) for the RGA and CG1S was swapped today by Anders and Isaac to provide clearance for the North Hot Cell ventilation. Attached photos show old and new locations.

Black "radio active" materials cabinet has been emptied, items bagged and removed from the anteroom. Cabinet itself has been swiped inside and out and also been removed from the anteroom. Most items have been removed from the anteroom now save some cardboard, rolls of plastic etc.

Testing was performed on August 9th on the ISAC nuclear ventilation system to determine if the existing ventilation system can achieve the required cell depressions for both SHC and NHC under all expected configurations and if a proposed modification to the DDC control system can provide acceptable stability and response time for the system.  The proposed control system observes the lower of the SHC depression or the NHC depression + 10% (to avoid stability issues), and adjusts the dampers to try to achieve 250Pa (1.00" WC) depression in the area it is observing.  With the proposed control system the SHC and NHC dampers are programmed to be at the same position, but can be tuned with a bias between them if required to achieve all ventilation requirements. The NHC and SHC dampers are programmed with a limit at 90% of the fully-open position.  There is a damper in the ducting system in the section of duct after the SHC and NHC legs join together;  this is set at 50% open, and was not adjusted during the the tests.  Test summary and results are listed below:

1.  Prior to switching to SHC+NHC control mode, the flow rate and depression of the SHC was measured with the lid on:  266Pa cell depression, damper 47% open, duct flow 417cfm.  The lid was opened and the measurements repeated:  35Pa, damper 90% open, duct flow 630cfm (results in 83ft/min, 0.42m/s average flow velocity across HC module opening)

2. The control system was switched to the new SHC+NHC single control loop system. Measurements were taken with both hot cell lids closed.  SHC:  246Pa, damper 72% open, 350cfm flow rate.  NHC: 257Pa, damper 72% open, 510cfm flow rate.  The ventilation fan speed was then increased from 53Hz to 57Hz (maximum speed is 60Hz).  Measurements were taken with both hot cell lids closed.  SHC:  257Pa, damper 51% open, 353cfm flow rate.  NHC: 257Pa, damper 51% open, 515cfm flow rate.

3. The SHC module port lid was opened and the NHC lid left closed.  SHC: 37Pa, damper 90% open, 462cfm (results in 61ft/min, 0.31m/s average flow velocity across HC module opening).  NHC: 249Pa, damper 90% open, 551cfm.

4. The NHC module port lid was opened and the SHC lid closed.  SHC: 203Pa, damper 90%, 360cfm.  NHC: 33Pa, damper 90%, 648cfm (results in 85ft/min, 0.44m/s average flow velocity across HC module opening).  The fan speed was then increased to 60Hz (max speed) to see if the depression setpoint for the SHC could be achieved in this configuration.  SHC: 231Pa, damper 90%, 389cfm.  NHC: 29Pa, damper 90%, 705cfm (results in 93ft/min, 0.47m/s average flow velocity across HC module opening)

5. Both SHC and NHC module port lids were opened and the fan was left at 60Hz.  SHC: 31Pa, damper 90%, 448cfm (results in 59ft/min, 0.30m/s average flow velocity across HC module opening).  NHC: 29Pa, 90% damper, 669cfm (results in 88ft/min, 0.45m/s average flow velocity across HC module opening)

For all tests the control system arrived at a stable depression value in less than 5 minutes, and thereafter exhibited only minor fluctuations.

Notes:

Duct flow rate was calculated assuming that measured flow velocity at the center of the duct is 90% of average duct velocity.  The duct ID at the sample location is 7.75", the hot cell opening size used for SHC and NHC module opening flow velocity calculations was 33" x 33".

Duct flow velocity measurements were taken using a thermal anemometer (Model number: 9555-P, Serial number: 9555:1108059 Rev. 2.11.0, Last calibrated by Rob Walker on April 29, 2016).

After completion of the tests the system was restored to it's original configuration and the ISAC target hall was swiped for contamination: none found.  No EF12 trips occurred during these tests.

Requested by Aurelia, and approved by Friedhelm, TM3 service tray cover plate ITA2108 has been remove out of the module. The plated is checked for active and contamination after removal. Then,It is double bagged, sealed ,  tagged, and placed downstairs in TH between south wall and green block . The ram contact reading on the plate is about 10 usv/hr.  We will do anther TM3 HV test at TCS without this cover plate.

Disassembled the master side of the right manipulator this morning to check the wrist cable. The cable on the master side shows no sign of wear or fraying suggesting that the slave side cable may be the item that is wearing. during disassembly of the master I did notice some loose parts that could have been the source of the audible concern but should not have contributed to the slippage felt in the gripper. I will try and schedule Tuesday for entry into the hot cell to address the slave cable.

Water cooling is performed manually with CP1. RGA is ON since yesterday. EE is not connected and in conditioning mode.

Friday, August 12, 2016, 10:43: BIAS at 10 kV, EL at 0.5 kV. IG1 at 1.8E-6 T

 Friday, August 12, 2016, 11:04: BIAS at 20 kV

Friday, August 12, 2016, 11:10: Sparking at 21 kV

Friday, August 12, 2016, 11:29: BIAS at 22 kV. Many small sparks/current excursions.

Friday, August 12, 2016, 11:32 : BIAS at 23 kV

Friday, August 12, 2016, 11:37: BIAS at 24 kV

Friday, August 12, 2016, 11:43: BIAS at 25 kV. Heavy sparking. Lowered to 24 kV to reduce spark rate.

Friday, August 12, 2016, 11:52: Increased sparking rate. Lowered to 23 kV.

Friday, August 12, 2016, 12:05: Lowered to 20 kV

Friday, August 12, 2016, 12:21: Back to 23 kV

Friday, August 12, 2016, 12:28: Heavy sparking between 23 and 24 kV. Lowered to 22 kV

Friday, August 12, 2016, 12:29: More sparking. Lowered to 21 kV.

Friday, August 12, 2016, 13:02: Increased back up to ~25 kV while Aurelia was listening for sparks in the Target Hall.

Friday, August 12, 2016, 13:03: EL to 10 kV

Friday, August 12, 2016, 13:06: BIAS / EL to 23 / 12.5 kV

Friday, August 12, 2016, 13:34: Repeated sparking at 24.5 kV. Ramping down

Friday, August 12, 2016, 15:33: Stopped water package. RGA off

Weekly update target hall schedule. Everything on schedule are finished  on time.   See attachment.