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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 ===


#; Medium-sized Peli case : Currently in Simon's office next to radiator.
==== Preparation for UCLH beam tests 29-30th April ====
: '''Due date: 20th October'''
 
:# Install Thorlabs optical breadboard in base of case.
# '''New scintillator stack holders:'''
:# Cut out  
#* 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


; 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.
; 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.
; 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


; July : Created CAD models for internal components including:  
; July : Created CAD models for internal components including:  
Line 33: Line 111:
: Machined two special 1/4-20 UNC screws for camera mount.
: 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.
: 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 ===
=== 2021 ===

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

  1. 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.
  2. 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).
  3. 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.
  4. 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

  1. 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.
  2. 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
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