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Electronic Log for Mechanical Engineering | Electronic Log for Mechanical Engineering | ||
== 2025 Experiment == | |||
=== Components inside the peli case=== | |||
:1. 4x detector modules: | |||
::1.1 128 polished scintillator sheets of 100x100x3mm (32 x module) | |||
::1.2 132 mylar foil sheets of 100x100x0.006mm (1 at the beginning of each module + 1 after each scintillator) | |||
::1.3 4x scintillator holders | |||
:2. Electronics: | |||
::2.1 256 photodiodes (32 sheets x 4 modules x 2 sides) | |||
::2.2 8 DDC232 revE boards | |||
::2.3 1 x Zmod daughter board | |||
::2.4 1 x FPGA USB104 | |||
:3. DAQ and cabling: | |||
::3.1 Raspberry pi5 for DAQ | |||
::3.2 8 usb C cables: 7 to daisy chain the scintillator modules + 1 for connection with Zmod | |||
::3.3 (Not confirmed yet) 7.5V power supplier for Zmod board (we need to test if it can be powered directly by the FPGA from the Zmod connection or not) | |||
::3.4 5V power supply cable for FPGA | |||
::3.5 USB for FPGA-Raspberry pi connection | |||
::3.6 Power cable for raspberry pi5 | |||
::3.7 Ethernet cable for pi5 | |||
== To Do == | == To Do == | ||
Line 5: | Line 29: | ||
=== Proton Therapy === | === Proton Therapy === | ||
# | ==== Preparation for UCLH beam tests 29-30th April ==== | ||
: ''' | |||
:# | # '''New scintillator stack holders:''' | ||
: | #* Stack holders 3D printed: remake by hand if time allows. | ||
#* Mounting plate to screw to Thorlabs optical breadboards in Peli cases: | |||
#** Rough version already 3D printed. | |||
#** Needs modifying to fix stack holder in place with M14(?) nuts. | |||
#** Must be able to mount upside down. | |||
#* New frame needed for patch panel with 50mm stand off to allow deeper connectors not to interfere with scintillator stacks. | |||
# '''Holder for NPL Transmission Calorimeter:''' | |||
#* TC needs to mount into Peli Case in front of stack holders. | |||
#* CAD STEP-files already received from Sam Flynn (NPL) for existing holder. | |||
#* If making new holder, exit pipe for electronics cabling needs to be shortened to fit in small Peli case. | |||
#* If making holder for holder, must mount to Thorlabs optical breadboard (M6 holes on 25mm pitch?). | |||
#* Centre of holder must be '''71 mm''' from baseplate (scintillator stacks are 50mm radius, plus 21mm offset from base). | |||
# '''Holder for Birmingham Pixel Sensor:''' | |||
#* '''Tony Price''' (Birmingham) has provided dimensions to '''HB'''. | |||
#* Holder needed to support pixel sensor between TC and scintillators. | |||
#* Peli case needs 100x10mm slot cut to left of side handle to allow sensor ribbon cable to pass through. | |||
# '''Nozzle mount for detector enclosure:''' | |||
#* Small Peli case needs to be nozzle-mounted for beam tests. | |||
#* Dimensions already obtained from UCLH measurements: | |||
#** '''SJ''' has contacted UCLH to check whether we can bypass light curtain. | |||
#** Assume we can't and design to bypass mechanically... | |||
#* 3 parts needed: | |||
#** Nozzle mounting plate that sits inside nozzle using range modulator plate mounting slots. | |||
#** U-bracket that slots in to this mounting plate — bypassing the light curtain — with a 40 x 30 cm hole for the beam to pass through. | |||
#** Peli Case support that fixes to the U-bracket and holds the Peli Case whilst gantry is rotating. | |||
==== May onwards ==== | |||
# '''Bari scintillating fibre holder:''' | |||
#* Bari are designing the scintillating fibre assembly for the '''QuADProBe'''. | |||
#* Prototype fibre array holder machined from aluminium. | |||
#* Clinical prototype ideally needs a version in plastic. | |||
#* Review Bari CAD drawings and recommend suitable materials. | |||
# '''Scintillator machining:''' | |||
#* Promising results from Datron: chase up potential workshops who could machine scintillator for us. | |||
#* Liaise with '''Martin Blackman''' in main workshop to assess quality of his scintillator machining. | |||
#* Write case and obtain quote for us to purchase Datron Neo. | |||
==== Full detector scintillator holder ==== | |||
* We need to go from the prototype version bolted to the optical plate to something completely standalone. | |||
* We can probably put it in another Peli case — I have loads — initially with an optical breadboard but eventually without. | |||
* It needs a support structure that is not rigidly bolted to the case but will align to any windows we cut: that means clinical staff can whack the detector and it won’t break or go out of alignment. So something internally sprung. | |||
== Completed == | == Completed == | ||
=== 2023 === | |||
; January-May : Enclosure design for small-scale Clatterbridge detector prototype (with Simon). | |||
:* Includes feedthroughs, mounts for NUC PC, Raspberry Pi and USB104 FPGA. | |||
:* Nozzle mounted | |||
=== 2022 === | === 2022 === | ||
; November-December : Design and 3D print external frame with alignment marks and alignment plates for small Peli case. | |||
: Duplicate alignment bar from Zarges case with circular studs to allow alignment with treatment couch. | |||
; October : Modified medium-sized Peli case ready for beam tests: | |||
:* Install Thorlabs optical breadboard in base of case. | |||
:* Cut out window at each end of case for mylar window installation. | |||
:* Cut out 2 windows for 2-gang patch panels, 1 per side. | |||
:* Cut out 2 windows for 1-gang patch panels, 1 per end. | |||
:* 3D print internal frames for mylar windows with bolt holes in each corner. Drill bolt holes in Peli case. | |||
:* 3D print external frame with alignment marks matching centre line of optical breadboard (vertical) and 71mm above optical breadboard (horizontal). Match bolt holes to mylar window frames. | |||
:* 3D print alignment plates that are strong enough to double as external cover plates when shipping enclosure. | |||
; September : Machine a patch panel complete with 10 smaller panels that can be swapped between on the main patch panel to allow for various electrical feedthroughs | ; September : Machine a patch panel complete with 10 smaller panels that can be swapped between on the main patch panel to allow for various electrical feedthroughs |
Latest revision as of 11:19, 3 December 2024
Electronic Log for Mechanical Engineering
2025 Experiment
Components inside the peli case
- 1. 4x detector modules:
- 1.1 128 polished scintillator sheets of 100x100x3mm (32 x module)
- 1.2 132 mylar foil sheets of 100x100x0.006mm (1 at the beginning of each module + 1 after each scintillator)
- 1.3 4x scintillator holders
- 2. Electronics:
- 2.1 256 photodiodes (32 sheets x 4 modules x 2 sides)
- 2.2 8 DDC232 revE boards
- 2.3 1 x Zmod daughter board
- 2.4 1 x FPGA USB104
- 3. DAQ and cabling:
- 3.1 Raspberry pi5 for DAQ
- 3.2 8 usb C cables: 7 to daisy chain the scintillator modules + 1 for connection with Zmod
- 3.3 (Not confirmed yet) 7.5V power supplier for Zmod board (we need to test if it can be powered directly by the FPGA from the Zmod connection or not)
- 3.4 5V power supply cable for FPGA
- 3.5 USB for FPGA-Raspberry pi connection
- 3.6 Power cable for raspberry pi5
- 3.7 Ethernet cable for pi5
To Do
Proton Therapy
Preparation for UCLH beam tests 29-30th April
- New scintillator stack holders:
- Stack holders 3D printed: remake by hand if time allows.
- Mounting plate to screw to Thorlabs optical breadboards in Peli cases:
- Rough version already 3D printed.
- Needs modifying to fix stack holder in place with M14(?) nuts.
- Must be able to mount upside down.
- New frame needed for patch panel with 50mm stand off to allow deeper connectors not to interfere with scintillator stacks.
- Holder for NPL Transmission Calorimeter:
- TC needs to mount into Peli Case in front of stack holders.
- CAD STEP-files already received from Sam Flynn (NPL) for existing holder.
- If making new holder, exit pipe for electronics cabling needs to be shortened to fit in small Peli case.
- If making holder for holder, must mount to Thorlabs optical breadboard (M6 holes on 25mm pitch?).
- Centre of holder must be 71 mm from baseplate (scintillator stacks are 50mm radius, plus 21mm offset from base).
- Holder for Birmingham Pixel Sensor:
- Tony Price (Birmingham) has provided dimensions to HB.
- Holder needed to support pixel sensor between TC and scintillators.
- Peli case needs 100x10mm slot cut to left of side handle to allow sensor ribbon cable to pass through.
- Nozzle mount for detector enclosure:
- Small Peli case needs to be nozzle-mounted for beam tests.
- Dimensions already obtained from UCLH measurements:
- SJ has contacted UCLH to check whether we can bypass light curtain.
- Assume we can't and design to bypass mechanically...
- 3 parts needed:
- Nozzle mounting plate that sits inside nozzle using range modulator plate mounting slots.
- U-bracket that slots in to this mounting plate — bypassing the light curtain — with a 40 x 30 cm hole for the beam to pass through.
- Peli Case support that fixes to the U-bracket and holds the Peli Case whilst gantry is rotating.
May onwards
- Bari scintillating fibre holder:
- Bari are designing the scintillating fibre assembly for the QuADProBe.
- Prototype fibre array holder machined from aluminium.
- Clinical prototype ideally needs a version in plastic.
- Review Bari CAD drawings and recommend suitable materials.
- Scintillator machining:
- Promising results from Datron: chase up potential workshops who could machine scintillator for us.
- Liaise with Martin Blackman in main workshop to assess quality of his scintillator machining.
- Write case and obtain quote for us to purchase Datron Neo.
Full detector scintillator holder
- We need to go from the prototype version bolted to the optical plate to something completely standalone.
- We can probably put it in another Peli case — I have loads — initially with an optical breadboard but eventually without.
- It needs a support structure that is not rigidly bolted to the case but will align to any windows we cut: that means clinical staff can whack the detector and it won’t break or go out of alignment. So something internally sprung.
Completed
2023
- January-May
- Enclosure design for small-scale Clatterbridge detector prototype (with Simon).
- Includes feedthroughs, mounts for NUC PC, Raspberry Pi and USB104 FPGA.
- Nozzle mounted
2022
- November-December
- Design and 3D print external frame with alignment marks and alignment plates for small Peli case.
- Duplicate alignment bar from Zarges case with circular studs to allow alignment with treatment couch.
- October
- Modified medium-sized Peli case ready for beam tests:
- Install Thorlabs optical breadboard in base of case.
- Cut out window at each end of case for mylar window installation.
- Cut out 2 windows for 2-gang patch panels, 1 per side.
- Cut out 2 windows for 1-gang patch panels, 1 per end.
- 3D print internal frames for mylar windows with bolt holes in each corner. Drill bolt holes in Peli case.
- 3D print external frame with alignment marks matching centre line of optical breadboard (vertical) and 71mm above optical breadboard (horizontal). Match bolt holes to mylar window frames.
- 3D print alignment plates that are strong enough to double as external cover plates when shipping enclosure.
- September
- Machine a patch panel complete with 10 smaller panels that can be swapped between on the main patch panel to allow for various electrical feedthroughs
- August
- Created CAD cross hair for Peli Case to be printed. Also created small printed windows to clamp Mylar smooth over the beam entry point.
- July
- Created CAD models for internal components including:
- Scintillator holder.
- 2x Side Vice faces.
- 1x Front Vice face.
- Cover for beam entry point.
- These were printed soon after.
- Beam entry point was cut out of the case, piece was sent for testing with Adam Gibson.
- Machined two special 1/4-20 UNC screws for camera mount.
- Tapped all holes on Scintillator holder to take m5 nylon screws to allow vice faces to travel.
- June
- Initiated design of large Peli Case. Received Lab scissor jack used to mount camera.
- May
- CAD Prototype a sliding system to mount multiple scintillator holders into a case
- February
- Create CAD model for small Peli Case so ideas on how to install the holder into the case can be prototyped
2021
- November
- Design initial prototype of a new holder that will clamp scintillator sheets together. Will supersede previous adhesive idea
- June
- Prepare scintillator sheets to be adhered together using standard primer