1. 1. Introduction and Overview
Mechanical Design Integration Peer Review, March 2003
1. Introduction and Overview
Martin Nordby
24 March 2003 rev 1

2. 1. Introduction & Overview
Mechanical Design Engineering Organization
Mechanical Design Overview
LAT layout and interface definitions
System block diagram
Design details
Design changes since Delta PDR
CCB’s: approved since Delta PDR and pending

3. Review Material
All presentation material and documentation is available on the web at:
Hard copies of all presentation material are reproduced in the binders available to reviewers
Hard copies of all documentation, back-up material, drawings, and reports are available for review

4. Mechanical Design Engineering Organization
LAT Organization
Since Delta PDR, LAT engineering organization and responsibilities have changed
Instrument Design Engineering group added
LAT Chief Engineer: Lowell Klaisner
Responsible for design integration, systems analysis, and fabrication planning for the LAT
Works with Systems Engineering to manage LAT interfaces and resolve interface and internal subsystem design issues
4.1.8 Mechanical Systems subsystem re-scoped to focus on flight hardware development, fabrication, and testing
Work Breakdown
Mechanical Design Integration
Part of Chief Engineer’s Design Engineering group
Interface design and development within and external to the LAT
Managing of LAT mechanical metrics: mass, dimensions, dissipated power
LAT structural and thermal analysis
Performing LAT-level design and trade studies
Flow-down of environmental and test parameters to LAT subsystems
LAT environmental test planning and technical management
Mechanical Systems
Design and development of Grid Box, Radiators, and heat pipes from subsystem requirements flowed down from LAT
Fabrication and verification testing of subsystem hardware and delivery to I&T group
Peer Reviews will follow this work breakdown
Mechanical Design Integration Peer Review: 26 Mar 2003
Mechanical Systems Peer Review: 27 Mar 2003

5. Mechanical Design Overview
LAT Structural Design Parameters
Design
Spec
Mass kg
<3000 kg
Center of Gravity
149.3 mm
<185 mm
Width
1806 mm
<1820 mm
Height mm
1100 mm
Tracker (TKR)
Mass
504.9 kg (Mar 2003 est)
Size
372 mm sq x 640 h
Interfaces
Grid Ti flexure mount and Cu strap
Calorimeter (CAL)
Mass
kg (Mar 2003 est)
Size
364 mm sq x 224 mm h
Interfaces
Grid bolted friction joint
Anticoincidence Detector (ACD)
Mass
270.1 kg (Mar 2003 est)
Size
1806 mm w x mm h
Interfaces
Grid bolted joint, shear pins
Grid/X-LAT Plate/Radiators
Mass
329.3 kg (Mar 2003 est)
Size
1580 mm sq x 236 mm h
Interfaces
Four-point mount to SC flexures
LAT Mass Budget and Current Estimates (kg)
Estimate
Budget
TKR
504.9
510.0
CAL
1375.8
1440.0
ACD
270.1
280.0
Mech
329.3
345.0
Elec
199.3
220.0
LAT Total
2679.4
3000
Source: LAT-TD “LAT Mass Status Report Mass Estimates for Mar 2003”
Electronics
Mass
199.3 kg (Mar 2003 est)
Size
1417 mm sq x 222 mm h
Interfaces
Stand-off to CAL; thermal joint to X-LAT Plate
LAT Overview

6. System Block Diagram LAT Block Diagram MLI Surrounding ACD ACD
Base Elec Ass’y alum frame
TKR Module
CFC tray, side walls
Grid
monolithic alum structure
Spacecraft
LAT mounting structure
Spacecraft
SC bus structure
CAL Modules
alum bottom plate
Solar Arrays
S.A. mount
Elec. Boxes
alum electronics box
EMI Skirt
Shields E-Boxes, supports X-LAT Pl
Radiator Mnt Bkt
Support Radiators at corners of Grid
LAT Radiators
on +/- Y sides of LAT Grid
X-LAT Plate
monolithic alum structure
Htr Switch Boxes
Operate Radiator heaters
MLI Insulation
MLI surrounding underside of LAT
LAT Block Diagram

7. LAT Design Details
Radiator Mount at Grid corners. Note mid-side Grid Wing
Grid corner detail showing heat pipes, purge grooves; corner chamfer and bottom flange for ACD
Copper thermal straps
Reverse-angle view of VCHP S-bends and DSHP connection
TKR mid-side and corner flexures

8. LAT Interface Details Grid Wing with SC mount bracket
EMI Skirt cut-outs around SC stay-clear
SC proposed interface stay-clear on top of octagonal SC volume
PAF, per Boeing PPG
LAT inside LV fairing static stay-clear

9. LAT Underside Design Details
Empty boxes
GASU box
SIU boxes
Upside-down view of a Grid Y mid-side, showing DSHP’s, Grid Wing, and EMI Skirt
PDU box
TPS (16x)
EPU boxes
TEM (16x)
LAT Underside View of Electronics Boxes
Detail of TEM, TPS, and EPU box stack

10. Design Changes Since Delta-PDR
Subsystem changes affecting system performance
TKR bottom tray re-work: strengthens CC tray in high-stress corner regions
TKR flexure re-design: accommodates updated bottom tray design and provides for stiffer cantilever mode for TKR
ACD mass growth: accommodates larger tile overlaps and increase in structural stiffness and strength
Interface changes
Wing bracket: re-designed to include vertical SC mount bracket hanging under Grid
TKR thermal straps: copper straps provide compliant joint to Grid
E-box mounting to CAL plate: E-boxes hard-mounted to CAL back plates now
X-LAT plate thermal connection: V-Therm cloth
CAL-Grid friction joint questioned by GSFC: currently investigating discussion

11. Design Changes Since Delta PDR (cont)
VCHP S-bends
SC-LAT mount region still in work
Radiator panels widened and shortened, reducing thermal efficiency
Panels cut-out locations fixed
LAT Delta PDR Design July 2002
LAT CDR Design Mar 2003

12. Change Control Board Changes Since Delta-PDR
ACD mass growth
Added structural mass to increase design margins
Added mass in scintillating tiles to increase size of tiles and overlap between tiles
Mechanical Systems mass growth
Added mass for Grid box additions: Grid Wing, bottom flange, EMI Skirt stiffening, X-LAT thermal straps
Added mass for slightly increased Radiator area
Calorimeter mass de-allocation
Decreased mass allocation to reflect reduction in size of CsI logs
Log size was reduced to accommodate tolerance stack-up within CFC box structure
Power allocation update (pending)
Updated power allocations based on current measured values
Already using updated allocations in thermal analysis