LHCb-VELO evaporatorCoBra Calculation and

feed through ideas.

18 February 2015

Bart Verlaat 1

Micro channel numbers

2

Cobra simulation of according previous slide

3

0 0.5 1 1.5 2 2.5 3-40

-35

-30

-25

-20

-15

Velo Upgrade temperature and pressure profile.MF=0.43 g/s, Tsp=-30ºC, Q

app=33 W, Q

env=0 W, x

end=0.25 dP=6.2 bar

Branch length (m)

Tem

pera

ture

(ºC

)

1 23 4 5

1x, D

=0.8

mm

19x,

D=0

.06m

m

19x,

D=0

.15m

m

1x, D

=1.5

mm

¯T

ur R

e=41

75

v

=0.8

m/s

¯T

ur R

e=41

75

v

=0.8

m/s

¯T

ur R

e=41

75

v

=0.8

m/s

¯T

ur R

e=41

75

v

=0.8

m/s

¯T

ur R

e=41

75

v

=0.8

m/s

¯B

ub x

=0.0

9

¯In

t x=

0.25

¯In

t x=

0.25

¯In

t x=

0.25

¯In

t x=

0.25

¯In

t x=

0.25

13

15

17

19

21

23

Pre

ssur

e(B

ar)

T Structure (ºC)

T Tube wall (ºC)

Tsat Fluid (ºC)T Fluid (ºC)

P Fluid (Bar)

CoBra simulation with reduced flow

4

0 0.5 1 1.5 2 2.5 3-40

-38

-36

-34

-32

-30

-28

-26

-24

-22

-20

Velo Upgrade temperature and pressure profile.MF=0.22 g/s, Tsp=-30ºC, Q

app=33 W, Q

env=0 W, x

end=0.5 dP=2.83 bar

Branch length (m)

Tem

pera

ture

(ºC

)

1 23 4 5

1x, D

=0.8

mm

19x,

D=0

.06m

m

19x,

D=0

.15m

m

1x, D

=1.5

mm

¯La

m R

e=20

96

v

=0.4

m/s

¯La

m R

e=20

96

v

=0.4

m/s

¯La

m R

e=20

96

v

=0.4

m/s

¯La

m R

e=20

96

v

=0.4

m/s

¯La

m R

e=20

96

v

=0.4

m/s

¯A

nnu

x=0

.2

¯S

W x

=0.5

¯S

W x

=0.5

¯S

W x

=0.5

¯S

W x

=0.5

¯S

W x

=0.5

11

12

13

14

15

16

17

18

19

20

21

Pre

ssur

e(B

ar)

T Structure (ºC)

T Tube wall (ºC)

Tsat Fluid (ºC)T Fluid (ºC)

P Fluid (Bar)

Flow more reduced……

5

0 0.5 1 1.5 2 2.5 3-40

-38

-36

-34

-32

-30

-28

-26

-24

-22

-20

Velo Upgrade temperature and pressure profile.MF=0.14 g/s, Tsp=-30ºC, Q

app=33 W, Q

env=0 W, x

end=0.75 dP=2.45 bar

Branch length (m)

Tem

pera

ture

(ºC

)

1 23 4 5

1x, D

=0.8

mm

19x,

D=0

.06m

m

19x,

D=0

.15m

m

1x, D

=1.5

mm

¯La

m R

e=13

98

v

=0.2

7 m

/s

¯La

m R

e=13

98

v

=0.2

7 m

/s

¯La

m R

e=13

98

v

=0.2

7 m

/s

¯La

m R

e=13

98

v

=0.2

7 m

/s

¯La

m R

e=13

98

v

=0.2

7 m

/s

¯S

W x

=0.3

1

¯S

W x

=0.7

5

¯S

W x

=0.7

5

¯S

W x

=0.7

5

¯S

W x

=0.7

5

¯S

W x

=0.7

5

10

11

12

13

14

15

16

17

18

19

20

Pre

ssur

e(B

ar)

T Structure (ºC)

T Tube wall (ºC)

Tsat Fluid (ºC)T Fluid (ºC)

P Fluid (Bar)

A reduced flow until X=0.9 => Dryout

6• Interesting the model does not show dry-out• Also very interesting: The pressure drop does not depend on flow!! I’ve never seen that….• Model must be crazy for microchannels, Test, test, test!!!

0 0.5 1 1.5 2 2.5 3-50

-45

-40

-35

-30

-25

-20

-15

-10

-5

0

Velo Upgrade temperature and pressure profile.MF=0.12 g/s, Tsp=-30ºC, Q

app=33 W, Q

env=0 W, x

end=0.89 dP=2.53 bar

Branch length (m)

Tem

pera

ture

(ºC

)

1 23 4 5

1x, D

=0.8

mm

19x,

D=0

.06m

m

19x,

D=0

.15m

m

1x, D

=1.5

mm

¯La

m R

e=11

74

v

=0.2

2 m

/s

¯La

m R

e=11

74

v

=0.2

2 m

/s

¯La

m R

e=11

74

v

=0.2

2 m

/s

¯La

m R

e=11

74

v

=0.2

2 m

/s

¯La

m R

e=11

74

v

=0.2

2 m

/s

¯S

W x

=0.3

7

¯S

W x

=0.8

9

¯S

W x

=0.8

9

¯S

W x

=0.8

9

¯S

W x

=0.8

9

¯S

W x

=0.8

9

10

11

12

13

14

15

16

17

18

19

20

Pre

ssur

e(B

ar)

T Structure (ºC)

T Tube wall (ºC)

Tsat Fluid (ºC)T Fluid (ºC)

P Fluid (Bar)

Reduced power.

7

0 0.5 1 1.5 2 2.5 3-35

-34

-33

-32

-31

-30

-29

-28

-27

-26

-25

Velo Upgrade temperature and pressure profile.MF=86.8 mg/s, Tsp=-30ºC, Q

app=16.5 W, Q

env=0 W, x

end=0.63 dP=1.2 bar

Branch length (m)

Tem

pera

ture

(ºC

)

1 23 4 5

1x, D

=0.8

mm

19x,

D=0

.06m

m

19x,

D=0

.15m

m

1x, D

=1.5

mm

¯La

m R

e=84

0

v

=0.1

6 m

/s

¯La

m R

e=84

0

v

=0.1

6 m

/s

¯La

m R

e=84

0

v

=0.1

6 m

/s

¯La

m R

e=84

0

v

=0.1

6 m

/s

¯La

m R

e=84

0

v

=0.1

6 m

/s

¯S

W x

=0.2

7

¯S

W x

=0.6

3

¯S

W x

=0.6

3

¯S

W x

=0.6

3

¯S

W x

=0.6

3

¯S

W x

=0.6

3

10

11

12

13

14

15

16

17

18

19

20

Pre

ssur

e(B

ar)

T Structure (ºC)

T Tube wall (ºC)

Tsat Fluid (ºC)T Fluid (ºC)

P Fluid (Bar)

Evaporator with connections outside vacuum

8

Connectors outside vacuum

Vacuum connector

Rolled up during handling

Insulation Vacuum

Cooling feed through

9

• 2x 1/8” VCR Gland (D=1/4”)• 1/8” VCR glands without nuts are very

small and fit both through a 14mm hole (10mm would even work)

• A split nut ala IBL can be installed after insertion

Hole diameter 14mm

Braze connection (Cold)

O ring connection (Warn)

1/8” VCR with splitnut

10

D=1/4” (6.35mm)

1/8” VCR with split nutAtlas-IBL cooling line

Cooling feed through and manifold vacuum box

11

Outlet manifoldVelo secondary vacuum

Inlet manifold

Cooling insulation vacuum

Flexible connections

VCR Split nut

Connection details outside vacuum (inside a tertiary vacuum box).