1. Thermal test (lab modules)
G. Riddone, A. Samoshkin
Last update 25-Jul-2011
Complement to the presentation on

2. Thermal tests
Investigation of the thermo-mechanical behaviour of the module following:
Variation of the ambient temperature
Variation of the RF structure temperature (PETS and accelerating structures)
Variation of the DB Quadrupole temperature
Validation of the FEA model by comparing results with simulated values

3. Measurements
Measurement of temperatures and comparison to simulations  BE-RF
Measurement of deformations/stresses and comparison to simulation  EN-MME (K. Artoos) + BE-RF
Measurement of the RF structure alignment  Method to be defined by SU

4. Module Type 0 cooling scheme

5. Power dissipation by T0 Lab Module components
* Technical Specification for the CLIC Two-Beam Module
G. RIDDONE EDMS *
DB Q
410 W
110 W
150 W
PETS  440 W
DB Q  300 W
AS  W

6. Heaters for T0 Test Module
max 480 W
1600 W
Max 3050 W
- One 80” (2024 mm) long heater for DB (PETS)
One 80” (2024 mm) long heater for MB (AS)
Sixteen 200W cartridges for DB (Quads)

7. 3D Integration layout

8. Measurements equipment configuration
Prepared by M. Sosin

9. Thermometers calibration
Calibration during slow cooling of heated copper block with all PT100
Polynomials calculation based on precision reference thermometer
Prepared by M. Sosin
BE/ABP Survey equipment will be borrowed

10. Sequence of the tests
Possibility to use IR camera to be investigated

11. Planning
Accelerating structure and PETS being assembled  several steps and learning process
QDB and BPM are available
The aim is to complete the assembly of the first module by end of 2011
Afterwards thermal tests can start