SPL RF power couplerthermal performance

Rossana Bonomi Rossana.Bonomi@cern.ch

ESS Cryomodule Status Meeting, 9/1/2013

Short Cryomodule

ESS Cryomodule Status Meeting, 9/1/2013

Simulation tool• Mathcad semi-

analytical model *• One dimensional• Mesh with 22 nodes

• 3 series of nodes (inner wall, outer wall, gas)

* Based on O. Capatina ‘s presentation: http://indico.cern.ch/getFile.py/access?contribId=3&resId=1&materialId=slides&confId=86123

ESS Cryomodule Status Meeting, 9/1/2013

Geometry • DWT length = 300 mm• Inner wall diameter = 100 mm• Cu sputter thickness = 4 um• Inner wall thickness = 1.5 mm• Outer wall thickness = 2 mm• Wall cross section = 1152 mm2

• Antenna diameter = 44 mm

ESS Cryomodule Status Meeting, 9/1/2013

ESS Cryomodule Status Meeting, 9/1/2013

Boundary conditions• Cold flange temperature = 2 K• Warm flange temperature = 300 K• Antenna temperature = 330 K• Inlet gas temperature = 4.5 K (1 bar)• Inlet gas mass flow = 40 mg/s• Convection coefficient = 40

W/m2/K

Material properties• Th-mech properties function of temperature

• Solids: Cryocomp• Fluid (helium): Hepak

ESS Cryomodule Status Meeting, 9/1/2013

Outer wall

Inner wall

Copper RRR=30

Material properties• Radiative properties function of temperature

• Copper on wall

ESS Cryomodule Status Meeting, 9/1/2013

Cuivre poli mequanique from “Cryogenie” 1995 – Blue book

Temperature profiles• Results are comparable

with FE 2D simulations (Comsol)• Heat load at bath:

< 0.5 W• RF power: around 10 W• Antenna radiation load:

around 1 W

Inner wall

No COOL

40 mg/s He

Outer wall

Inner wall

Gas

RF power distribution• RF currents node position is

critical ..• 704 MHz, 50 ohm• Power: 1 MWp

• Duty cycle: 10%• Current: = 200 Ap

RF currents

ESS Cryomodule Status Meeting, 9/1/2013

RF power distribution

RF currents

ESS Cryomodule Status Meeting, 9/1/2013

• RF currents node position is critical ..

currents

power

Sensitivity analysis: RF node• No cooling

ESS Cryomodule Status Meeting, 9/1/2013

Shift [mm]

P rf [W]

Q rad [W]

Q bath [W]

0 23.688 0.753 24.381

10 24.863 0.767 24.799

20 25.940 0.785 25.110

50 27.738 0.840 25.159

100 24.682 0.823 23.034

CF

CF

Sensitivity analysis: RF node• Gas cooling with 40 mg/s

ESS Cryomodule Status Meeting, 9/1/2013

Shift [mm]

P rf[W]

Q rad [W]

Q bath [W]

0 10.208 1.346 0.104

10 11.425 1.354 0.121

20 12.660 1.360 0.155

50 15.531 1.369 0.338

100 14.136 1.349 0.538

CF

Sensitivity analysis: Mass flow

ESS Cryomodule Status Meeting, 9/1/2013

Mass flow(mg/s)

Qheater(W)

Prf(W)

Qrad(W)

Qbath (W)

0 0 23.688 0.753 24.381

30 32.722 12.542 1.461 0.151

40 49.669 10.208 1.346 0.104

50 63.629 9.667 1.284 0.103

• RF node @ cold flange (shift = 0)

Conclusions

ESS Cryomodule Status Meeting, 9/1/2013

• Mathematical tool can be tuned to simulate different geometries and cryo fluids

• Looking forward to the mock-up test for confirmation of this model

• ..and to suggestions !

• THANK YOU !

Operating condition Value

Beam current/pulse lenght 40 mA/0.4 ms beam pulse

20 mA/0.8 ms beam pulse

cryo duty cycle 4.11% 8.22%

quality factor 10 x 109 5 x 109

accelerating field 25 MV/m 25 MV/m

Source of Heat Load Heat Load @ 2K

Beam current/pulse lenght 40 mA/0.4 ms beam pulse 20 mA/0.8 ms beam pulse

dynamic heat load per cavity 5.1 W 20.4 W

static losses <1 W (tbc) <1 W (tbc)

power coupler loss at 2 K <0.2 W <0.2 W

HOM loss in cavity at 2 K <1 <3 W

HOM coupler loss at 2 K (per coupl.)

<0.2 W <0.2 W

beam loss 1 W

Total @ 2 K 8.5 W 25.8 W

SPL operational conditions

(Figure from: « An Introduction to Cryogenics », Ph.Lebrun, CERN/AT 2007-1)

He refrigeration He Liquefaction

Thermodynamic efficiency of gas cooling

• Electrical power for liquefaction of 1 g/s helium: 6200 Wel

• Carnot COP @ 4.5 K: 66 Wel/Wth

• 1 g/s liquid helium is equivalent to 100 Wth @ 4.5 K *

* U. Wagner s presentation: http://cdsweb.cern.ch/record/808372/files/p295.pdf

ESS Cryomodule Status Meeting, 9/1/2013

Thermodynamic efficiency of gas cooling

• Comparison with other ways of cooling (heat intercepts, self-sustained cooling)

• 990 @ 2 K, 220 @ 9 or 4.5 K, 16 @ 80 KCase Q @ 2K

[W]P [Wel]

Q @ 9K [W]

P [Wel]

Q @ 80K[W]

P [Wel]

vapours rate[g/s]

Q equiv. @ 4.5K

[W] (1g/s=100W)

P [Wel]

Total power[Wel]

A) No intercept 12.6 12,375  - -      - -  -  12,375B) 1 optimised intercept @ 80K 2.2 2,178  - -  44.6 714  - -  -  2,892

C) 2 optimised intercepts @ 80K & 9K 0.18 178 3.2 704 30.6 490  - -  -  1,372

D) 4.5K self-sustained vapour cooling 0.03 30 -   -  -  - 0.020 2 440 470

E) He vapour cooling (4.5K-300K) 0.10 99 -   - -   - 0.04 4 880 979

F) He vapour cooling (4.5K-300K),RF power on

0.50 495 -  -  -  - 0.04 4 880 1,375

G) No He vapour cooling,RF power on 22 21,780  - -   -  - 0 0 0 21,780

ESS Cryomodule Status Meeting, 9/1/2013

(B) 1 Heat intercept

Q @ 2K

300K

x1

L

Q @ 80K

(C) 2 Heat intercepts

Q @ 2K

300K

Q @ 8K

Q @ 80K

L

x 1

x 2

(D) He vapour cooling

300K

4.5K

Q in g/s

L

attenuation factor

Geometry

Geometry

Mesh

CF WF