ELogs/MechanicalEngineering: Difference between revisions
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=== Proton Therapy === | === Proton Therapy === | ||
==== Medium-sized Peli case ==== | |||
* '''Due date: 20th October''' | |||
* Currently in Simon's office next to radiator. | |||
# Install Thorlabs optical breadboard in base of case. | |||
# Cut out window at each end of case for mylar window installation. | |||
#* Max width 20cm. | |||
#* Bottom of window level with optical breadboard. | |||
#* Top of window flush with handle support struts. | |||
# 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. | |||
==== Small Peli case ==== | |||
* '''Due date: 20th October''' | |||
# 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. | |||
* '''Due date: 30th November''' | |||
# Duplicate alignment bar from Zarges case with circular studs to allow alignment with treatment couch. | |||
==== Clatterbridge detector ==== | |||
- | * Design enclosure for small-scale Clatterbridge prototype (with Simon). | ||
* Internal volume approx 15 x 15 x 15cm. | |||
* Needs to contain 16-sheet scintillator stack and FPGA with patch panel for FPGA and power connections. | |||
* Raspberry Pi mounted externally. | |||
* Light enough to mount directly to Clatterbridge nozzle; double sided so mountable from both directions. Whole structure hangs off nozzle. | |||
==== 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 == | ||
| Line 43: | Line 50: | ||
=== 2022 === | === 2022 === | ||
; 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 === | === 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 | |||
Revision as of 17:33, 20 September 2022
Electronic Log for Mechanical Engineering
To Do
Proton Therapy
Medium-sized Peli case
- Due date: 20th October
- Currently in Simon's office next to radiator.
- Install Thorlabs optical breadboard in base of case.
- Cut out window at each end of case for mylar window installation.
- Max width 20cm.
- Bottom of window level with optical breadboard.
- Top of window flush with handle support struts.
- 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.
Small Peli case
- Due date: 20th October
- 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.
- Due date: 30th November
- Duplicate alignment bar from Zarges case with circular studs to allow alignment with treatment couch.
Clatterbridge detector
- Design enclosure for small-scale Clatterbridge prototype (with Simon).
- Internal volume approx 15 x 15 x 15cm.
- Needs to contain 16-sheet scintillator stack and FPGA with patch panel for FPGA and power connections.
- Raspberry Pi mounted externally.
- Light enough to mount directly to Clatterbridge nozzle; double sided so mountable from both directions. Whole structure hangs off nozzle.
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
2022
- 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