An annual electrical inspection was performed on the SMP today by Travis Cave and Nadia Jorgenson as per Work Permit I2022-06-30-2. The following items were checked:

Electrical Inspection of Safe Module Parking:

• Check condition of wiring for physical/radiation/UV damage
  • OK, no signs of damage
• Check for cable tray debris or damage
  • Some objects stored in the cable tray but nothing concerning, no damage noted
• Check inside control panel: components and wiring, labeling
  • Labeling intact, components in good condition
  • Wiring in good condition
• Verify camera views
  • Checked, no issues
• Check connectors for damage
  • All connectors OK
• Check pendant for damage and verify labeling intact
  • Pendant OK
• Lid open/close test
  • Lid was opened and close multiple times - smooth operation, no concern
  • Lid close logic was checked - OK
• Vessel rotation and limit switch check
  • Centre, CW and CCW limits were checked, functioning

Still to be done – Mechanical Inspection:

• Lubricate chains
• Inspect tensioners
• Tighten fasteners
• Inspect components during rotation - chain drive, rotary limit switch, and cable reel etc.

An annual mechanical inspection was performed on the SMP today by Dan McDonald and Nadia Jorgenson. The following items were checked:

• Lubricate chains
  • Not needed
• Inspect tensioners
  • No issues found
• Tighten fasteners
  • A few slightly loose, most are in need of washers, see attached pictures
  • Could use some shims in a few places, see attached picture
• Inspect components during rotation - chain drive, rotary limit switch, and cable reel etc.
  • No issues

 TM2 with no target on SW silo be electrical checked right after module moving.

SMP  vacuum pumping down is stopped. SMP and TM4 venting to atmosphere will be started soon.

An annual electrical and mechanical inspection was performed on the SMP today by Adam Newsome, Travis Cave, Eric Lahe, Maico Dalla Valle, Antoniette Yap, and Jason Zhang as per Work Permit I2023-06-21-4. The following items were checked:

• Check condition of wiring for physical/radiation/UV damage
  • OK, no signs of significant damage
• Check for cable tray debris or damage
  • There were multiple items in the cable tray which do not belong there - misc. pieces of wood and metal... these items were not disposed of but should be in the near future
• Check inside control panel: components and wiring, labeling
  • Labeling intact, components in good condition
  • Misc. random wires pulled to check... one ground wire was loose - it was tightened
• Verify camera views
  • This was not inspected in detail but signal status was checked, and is checked prior to remote operation
• Check connectors for damage
  • All connectors OK
• Check pendant for damage and verify labeling intact
  • Pendant OK
• Lid open/close test
  • Lid was opened and close multiple times - smooth operation, no concern
  • Lid close logic was checked - OK
• Vessel rotation and limit switch check
  • Both CW and CCW limits were checked, functioning
  • No concern on rotation - chain drive, rotary limit switch, and cable reel all functioning normally
• Lubricate chains
  • Not done - should be done next year
• Inspect tensioners
  • Done - OK
• Tighten fasteners
  • Not all fasteners were checked - washers will be replaced soon so this was not deemed necessary
  • Approximately 50 washers are missing for socket head screws in slotted parts. Not safety critical but they should be replaced soon.
• Visual inspection
  • All OK

Overall the inspection was successful.

TM4 has been moved to SMP. The move is smooth. I started SMP vacuum pump. The TM4 and SMP vessel is under vacuum now.

TM4 coil1, 2 and HS are all OL at 250V at SMP after module move. This week, Chad and Carl fixed short issue on coil1, 2 and HS by insert dropped ultem ring back to position at SHC.

An annual electrical and mechanical inspection was performed on the SMP today by Adam Newsome, Travis Cave, Riley Sykes, Maico Dalla Valle, and Jason Zhang as per Work Permit  I2024-07-10-1. The following items were checked:

• Check condition of wiring for physical/radiation/UV damage
  • OK, no signs of significant damage
• Check for cable tray debris or damage
  • There were multiple items in the cable tray which do not belong there - misc. pieces of wood and metal... these items were not disposed of but should be in the near future
• Check inside control panel: components and wiring, labeling
  • Labeling intact, components in good condition
  • Misc. random wires pulled to check... OK
• Verify camera views
  • This was not inspected in detail as it is something that would be done prior to remote operation
• Check connectors for damage
  • All connectors OK
• Check pendant for damage and verify labeling intact
  • Pendant OK
• Lid open/close test
  • Lid was opened and close multiple times - smooth operation, no concern
  • Lid close logic was checked - OK
• Vessel rotation and limit switch check
  • Both CW and CCW limits were checked, functioning
  • No concern on rotation - chain drive, rotary limit switch, and cable reel all functioning normally
• Lubricate chains
  • Not done - should be done next year
• Inspect tensioners
  • Done - OK
• Tighten fasteners
  • Not all fasteners were checked - washers will be replaced soon so this was not deemed necessary
  • Approximately 50 washers are missing for socket head screws in slotted parts. Not safety critical but they should be replaced soon.
• Visual inspection
  • All OK

Overall the inspection was successful.

 SS washers were added to all slotted holes on SMP chainguard cover plate

 SMP:MP1 is started with SMP BV1 is opened. SMP is under vacuum for TM4 storage during shut down.

An informal inspection of the main Pail Handling Tool was performed today as the final one for the year. Note that the main formal annual inspection was performed June 18, 2024 for this year.

The attachment to this e-log serves as a record of all inspections for this tool throughout 2024.

The spare tool was not inspected as it was not in service this year.

A meeting was held on May 4, 2016 to determine the scope of the North Hot Cell project.  The following was agreed upon by those in attendance:

The NHC will be a designated target change hot cell.  It will be capable of performing all routine target operations (target removal/installation, leak check, electrical check, video inspection, post irradiation examination, target waste packaging and removal) using the same method currently used in the south hot cell.  Provisions will be included for the ability to perform target waste separation in the future unless a significant obstacle is encountered in which case the meeting attendees will be consulted.  Target waste separation involves separating the internal target heater from the target heat shield, then combining multiple target heaters in a single F-308 shipment.  Neither an inert gas atmosphere nor a double-door waste transfer system will be part of the NHC scope.

The following people were in attendance:  Bob Laxdal, Anders Mjos, Don Jackson, Joe Mildenberger, Friedhelm Ames, Alex Gottberg, Grant Minor, Yasmine Saboui, Peter Kunz

The following people were invited, but were unable to attend:  Chad Fisher, Pierre Bricault

The project will begin immediately, with Isaac Earle as the project leader.  The first steps will be to submit a Project Initiation Sheet, then to write and release the Requirements Specification document.

 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"

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.

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.

 Measurements were taken today of the NHC north/south wall gap at the location where the NHC/TCS partition wall will be installed (43.375" from the NHC west wall).  A HILTI PD40 laser range meter was used for the measurements.  They were taken at 10", 34", 62", 90", 118", and 142" from the floor which matches the top of each cross-beam.  The results are below:

10" from floor:  102.44"
34" from floor:  102.40"
62" from floor:  102.48"
90"  from floor:  102.63"
118" from floor:  102.28"
142" from floor:  102.24"

Based on these results a partition wall plate width of 102.00" will be used for the bottom two plates, and 102.25" for the upper three plates in order to keep the gap on each side approximately 1/8"

The sheet metal panel covering the NHC/SHC feedthrough port was removed today using a slide-hammer to pull out the concrete anchors (this oversized panel would have interfered with the NHC partition wall).  50cpm was found on the inside of the panel, 100cpm on the NHC side lip of the feedthrough, and 350cpm on the face of the shielding bricks in the feedthrough.  Various dimensional measurements of the feedthrough were taken which will be added to the partition wall Solidworks model (IRH1609).  The panel was bagged for disposal and a temporary 20"x20" panel was put over the feedthrough and secured with duct tape.  A permanent panel with anchored supports that is compatible with the NHC partition wall will be designed and installed at a later date.  A swipe of the NHC walls and floor picked up 30cpm after completion of the job.  

David Wang and I accessed the NHC today to check if the proposed duct routing (IRH1618) will interfere with servicing or replacement of the TCS turbo pump.  A piece of plywood was placed in the future position of the NHC/TCS partition wall (IRH1609), and a ducting elbow was placed at the approximate position of the nearest elbow to the turbo pump.

David concluded that the ducting in the proposed location will not have any significant effect on replacement of the turbo pump, and he does not expect replacement will be difficult to perform after installation of the wall and NHC ducting.  Standing at floor level towards the east side of the TCS space and reaching upwards seemed to be the best way to reach the turbo pump flange bolts.  It was also noted that there was sufficient room in the TCS space for two workers to be in the area.

 The concrete floor in the North Hot Cell service area and the top of the NHC roof block in the target hall have been painted with Macropoxy 646 oil based epoxy paint, colour Flint Grey.  Two coats were used for the NHC roof, and one for the service area floor.

 The new ducting section connecting the existing duct termination in the TCS space to the NHC partition wall has been installed by Smith Sheet Metal contractors.  The installation drawing is IRH1618.  There was not enough clearance between the duct pipe and the TCS vessel to butt weld the new ductwork as originally intended.  Instead a flange was welded to the existing pipe and also to the new section and the two were bolted together.  Drawings of the modifications have been provided by the contractor, and as-built drawings will be completed at a later date.  There was not time for the contractor to fabricate a gasket for the flanged joint, so one will be installed by TRIUMF at a later date and included in the as-built drawing package.