JINR PACDubna 26012012

JINR PACDubna 26012012

G Gulbekian

Status of the DRIBs III Project

bull cyclotron DC280bull new experimental hall (SHE factory)bull cyclotron U400Rbull reconstruction of the U400R experimental hall

Future accelerators for SHE programs

Center Accelerator type Intensity 48Са pA Realization

MSU SC Linac 10 2018divide2020

SPIRAL II SC Linac 10 2013divide2016

GSI SC Linac 10 2013divide2015

RIKEN Ring Cyclotron 10 2011divide2013

Dubna Compact Cyclotron 10 2014

In order to improve efficiency of the experiments for the

next 7 years it is necessary to obtain the accelerated ion beams

with following parameters

Energy 4divide8 MeVn

Masses 10divide238

Intensity (up to A=50) gt10 pmicroA

Beam emittance less 30 π mmmrad

Efficiency of beam transfer gt50

NEW FLNR ACCELERATOR ndash NEW FLNR ACCELERATOR ndash DC280 CYCLOTRONDC280 CYCLOTRON

4

DC280 Parameter Goals

1 High injecting beam energy (up to 100 kV)

Shift of space charge limits for factor 30

2 High gap in the center Space for long spiral inflector

3 Low magnetic field Large starting radius High turns separation Low deflector voltage

4 High acceleration rate High turns separation

5 Flat-top system High capture Single orbit extraction Beam quality

DC280 Parameters and Goals

0 01 02 03 04 05 06 07 08 09 1 11 12 13In jected current м А

0

15

30

45

60

75

Effi

cien

cy

A Z=6

A Z=5

A Z=4U 400(U in j=15кV)E xperim enta l da ta

D C 280(U in j=50кV)

A Z=10

DC280 Overall (ion source target) beam current

transferring efficiency

DC280 Planning Lay-out

Working Diagram of the DC280 Cyclotron

Ion source DECRIS-4DECRIS-4 - 14 GHz - 14 GHzDECRIS-SC3 - 18 GHz- 18 GHz

Injecting beam potential Up to 100 kV

AZ range 4divide7

Energy 4divide8 MeVn

Magnetic field level 06divide135 T

K factor 280

Gap between plugs 400 mm

Valleyhill gap 500208 mmmm

Magnet weight 1000 t

Magnet power 300 kW

Dee voltage 2x130 kV

RF power consumption 2x30 kW

Flat-top dee voltage 2x14 kV

DC280 Main Parameters

Flerovlab Building 131

New Experimental Building with DC280 accelerator complex

Basement Rooms

First Floor

Second Floor

Third floor

SHE factory

Building computer model

DC280 Cyclotron intensity of some typical ion beams

20Ne 1middot1014 pps

48Ca 6middot1013 pps

50Ti 3middot1013 pps

70Zn 25middot1013 pps

86Kr 3middot1013 pps

100Mo 2middot1012 pps

124Sn 2middot1012 pps

136Xe 2middot1013 pps

208Pb 1middot1012 pps

238U 1middot1011 pps

FLNR

Schedule of the SHE factory creation

Modernization of the U400 accelerator

bull improvement of the quality and intensity of stable and radioactive beams (48Ca ndash 25divide3 pA )

bull providing of a smooth variation of energy of ions

in the range 08 ndash 27 MeVA

bull decrease in the consumption of rare isotopes bull decrease in power consumption

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

Future accelerators for SHE programs

Center Accelerator type Intensity 48Са pA Realization

MSU SC Linac 10 2018divide2020

SPIRAL II SC Linac 10 2013divide2016

GSI SC Linac 10 2013divide2015

RIKEN Ring Cyclotron 10 2011divide2013

Dubna Compact Cyclotron 10 2014

In order to improve efficiency of the experiments for the

next 7 years it is necessary to obtain the accelerated ion beams

with following parameters

Energy 4divide8 MeVn

Masses 10divide238

Intensity (up to A=50) gt10 pmicroA

Beam emittance less 30 π mmmrad

Efficiency of beam transfer gt50

NEW FLNR ACCELERATOR ndash NEW FLNR ACCELERATOR ndash DC280 CYCLOTRONDC280 CYCLOTRON

4

DC280 Parameter Goals

1 High injecting beam energy (up to 100 kV)

Shift of space charge limits for factor 30

2 High gap in the center Space for long spiral inflector

3 Low magnetic field Large starting radius High turns separation Low deflector voltage

4 High acceleration rate High turns separation

5 Flat-top system High capture Single orbit extraction Beam quality

DC280 Parameters and Goals

0 01 02 03 04 05 06 07 08 09 1 11 12 13In jected current м А

0

15

30

45

60

75

Effi

cien

cy

A Z=6

A Z=5

A Z=4U 400(U in j=15кV)E xperim enta l da ta

D C 280(U in j=50кV)

A Z=10

DC280 Overall (ion source target) beam current

transferring efficiency

DC280 Planning Lay-out

Working Diagram of the DC280 Cyclotron

Ion source DECRIS-4DECRIS-4 - 14 GHz - 14 GHzDECRIS-SC3 - 18 GHz- 18 GHz

Injecting beam potential Up to 100 kV

AZ range 4divide7

Energy 4divide8 MeVn

Magnetic field level 06divide135 T

K factor 280

Gap between plugs 400 mm

Valleyhill gap 500208 mmmm

Magnet weight 1000 t

Magnet power 300 kW

Dee voltage 2x130 kV

RF power consumption 2x30 kW

Flat-top dee voltage 2x14 kV

DC280 Main Parameters

Flerovlab Building 131

New Experimental Building with DC280 accelerator complex

Basement Rooms

First Floor

Second Floor

Third floor

SHE factory

Building computer model

DC280 Cyclotron intensity of some typical ion beams

20Ne 1middot1014 pps

48Ca 6middot1013 pps

50Ti 3middot1013 pps

70Zn 25middot1013 pps

86Kr 3middot1013 pps

100Mo 2middot1012 pps

124Sn 2middot1012 pps

136Xe 2middot1013 pps

208Pb 1middot1012 pps

238U 1middot1011 pps

FLNR

Schedule of the SHE factory creation

Modernization of the U400 accelerator

bull improvement of the quality and intensity of stable and radioactive beams (48Ca ndash 25divide3 pA )

bull providing of a smooth variation of energy of ions

in the range 08 ndash 27 MeVA

bull decrease in the consumption of rare isotopes bull decrease in power consumption

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

In order to improve efficiency of the experiments for the

next 7 years it is necessary to obtain the accelerated ion beams

with following parameters

Energy 4divide8 MeVn

Masses 10divide238

Intensity (up to A=50) gt10 pmicroA

Beam emittance less 30 π mmmrad

Efficiency of beam transfer gt50

NEW FLNR ACCELERATOR ndash NEW FLNR ACCELERATOR ndash DC280 CYCLOTRONDC280 CYCLOTRON

4

DC280 Parameter Goals

1 High injecting beam energy (up to 100 kV)

Shift of space charge limits for factor 30

2 High gap in the center Space for long spiral inflector

3 Low magnetic field Large starting radius High turns separation Low deflector voltage

4 High acceleration rate High turns separation

5 Flat-top system High capture Single orbit extraction Beam quality

DC280 Parameters and Goals

0 01 02 03 04 05 06 07 08 09 1 11 12 13In jected current м А

0

15

30

45

60

75

Effi

cien

cy

A Z=6

A Z=5

A Z=4U 400(U in j=15кV)E xperim enta l da ta

D C 280(U in j=50кV)

A Z=10

DC280 Overall (ion source target) beam current

transferring efficiency

DC280 Planning Lay-out

Working Diagram of the DC280 Cyclotron

Ion source DECRIS-4DECRIS-4 - 14 GHz - 14 GHzDECRIS-SC3 - 18 GHz- 18 GHz

Injecting beam potential Up to 100 kV

AZ range 4divide7

Energy 4divide8 MeVn

Magnetic field level 06divide135 T

K factor 280

Gap between plugs 400 mm

Valleyhill gap 500208 mmmm

Magnet weight 1000 t

Magnet power 300 kW

Dee voltage 2x130 kV

RF power consumption 2x30 kW

Flat-top dee voltage 2x14 kV

DC280 Main Parameters

Flerovlab Building 131

New Experimental Building with DC280 accelerator complex

Basement Rooms

First Floor

Second Floor

Third floor

SHE factory

Building computer model

DC280 Cyclotron intensity of some typical ion beams

20Ne 1middot1014 pps

48Ca 6middot1013 pps

50Ti 3middot1013 pps

70Zn 25middot1013 pps

86Kr 3middot1013 pps

100Mo 2middot1012 pps

124Sn 2middot1012 pps

136Xe 2middot1013 pps

208Pb 1middot1012 pps

238U 1middot1011 pps

FLNR

Schedule of the SHE factory creation

Modernization of the U400 accelerator

bull improvement of the quality and intensity of stable and radioactive beams (48Ca ndash 25divide3 pA )

bull providing of a smooth variation of energy of ions

in the range 08 ndash 27 MeVA

bull decrease in the consumption of rare isotopes bull decrease in power consumption

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

4

DC280 Parameter Goals

1 High injecting beam energy (up to 100 kV)

Shift of space charge limits for factor 30

2 High gap in the center Space for long spiral inflector

3 Low magnetic field Large starting radius High turns separation Low deflector voltage

4 High acceleration rate High turns separation

5 Flat-top system High capture Single orbit extraction Beam quality

DC280 Parameters and Goals

0 01 02 03 04 05 06 07 08 09 1 11 12 13In jected current м А

0

15

30

45

60

75

Effi

cien

cy

A Z=6

A Z=5

A Z=4U 400(U in j=15кV)E xperim enta l da ta

D C 280(U in j=50кV)

A Z=10

DC280 Overall (ion source target) beam current

transferring efficiency

DC280 Planning Lay-out

Working Diagram of the DC280 Cyclotron

Ion source DECRIS-4DECRIS-4 - 14 GHz - 14 GHzDECRIS-SC3 - 18 GHz- 18 GHz

Injecting beam potential Up to 100 kV

AZ range 4divide7

Energy 4divide8 MeVn

Magnetic field level 06divide135 T

K factor 280

Gap between plugs 400 mm

Valleyhill gap 500208 mmmm

Magnet weight 1000 t

Magnet power 300 kW

Dee voltage 2x130 kV

RF power consumption 2x30 kW

Flat-top dee voltage 2x14 kV

DC280 Main Parameters

Flerovlab Building 131

New Experimental Building with DC280 accelerator complex

Basement Rooms

First Floor

Second Floor

Third floor

SHE factory

Building computer model

DC280 Cyclotron intensity of some typical ion beams

20Ne 1middot1014 pps

48Ca 6middot1013 pps

50Ti 3middot1013 pps

70Zn 25middot1013 pps

86Kr 3middot1013 pps

100Mo 2middot1012 pps

124Sn 2middot1012 pps

136Xe 2middot1013 pps

208Pb 1middot1012 pps

238U 1middot1011 pps

FLNR

Schedule of the SHE factory creation

Modernization of the U400 accelerator

bull improvement of the quality and intensity of stable and radioactive beams (48Ca ndash 25divide3 pA )

bull providing of a smooth variation of energy of ions

in the range 08 ndash 27 MeVA

bull decrease in the consumption of rare isotopes bull decrease in power consumption

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

0 01 02 03 04 05 06 07 08 09 1 11 12 13In jected current м А

0

15

30

45

60

75

Effi

cien

cy

A Z=6

A Z=5

A Z=4U 400(U in j=15кV)E xperim enta l da ta

D C 280(U in j=50кV)

A Z=10

DC280 Overall (ion source target) beam current

transferring efficiency

DC280 Planning Lay-out

Working Diagram of the DC280 Cyclotron

Ion source DECRIS-4DECRIS-4 - 14 GHz - 14 GHzDECRIS-SC3 - 18 GHz- 18 GHz

Injecting beam potential Up to 100 kV

AZ range 4divide7

Energy 4divide8 MeVn

Magnetic field level 06divide135 T

K factor 280

Gap between plugs 400 mm

Valleyhill gap 500208 mmmm

Magnet weight 1000 t

Magnet power 300 kW

Dee voltage 2x130 kV

RF power consumption 2x30 kW

Flat-top dee voltage 2x14 kV

DC280 Main Parameters

Flerovlab Building 131

New Experimental Building with DC280 accelerator complex

Basement Rooms

First Floor

Second Floor

Third floor

SHE factory

Building computer model

DC280 Cyclotron intensity of some typical ion beams

20Ne 1middot1014 pps

48Ca 6middot1013 pps

50Ti 3middot1013 pps

70Zn 25middot1013 pps

86Kr 3middot1013 pps

100Mo 2middot1012 pps

124Sn 2middot1012 pps

136Xe 2middot1013 pps

208Pb 1middot1012 pps

238U 1middot1011 pps

FLNR

Schedule of the SHE factory creation

Modernization of the U400 accelerator

bull improvement of the quality and intensity of stable and radioactive beams (48Ca ndash 25divide3 pA )

bull providing of a smooth variation of energy of ions

in the range 08 ndash 27 MeVA

bull decrease in the consumption of rare isotopes bull decrease in power consumption

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

DC280 Planning Lay-out

Working Diagram of the DC280 Cyclotron

Ion source DECRIS-4DECRIS-4 - 14 GHz - 14 GHzDECRIS-SC3 - 18 GHz- 18 GHz

Injecting beam potential Up to 100 kV

AZ range 4divide7

Energy 4divide8 MeVn

Magnetic field level 06divide135 T

K factor 280

Gap between plugs 400 mm

Valleyhill gap 500208 mmmm

Magnet weight 1000 t

Magnet power 300 kW

Dee voltage 2x130 kV

RF power consumption 2x30 kW

Flat-top dee voltage 2x14 kV

DC280 Main Parameters

Flerovlab Building 131

New Experimental Building with DC280 accelerator complex

Basement Rooms

First Floor

Second Floor

Third floor

SHE factory

Building computer model

DC280 Cyclotron intensity of some typical ion beams

20Ne 1middot1014 pps

48Ca 6middot1013 pps

50Ti 3middot1013 pps

70Zn 25middot1013 pps

86Kr 3middot1013 pps

100Mo 2middot1012 pps

124Sn 2middot1012 pps

136Xe 2middot1013 pps

208Pb 1middot1012 pps

238U 1middot1011 pps

FLNR

Schedule of the SHE factory creation

Modernization of the U400 accelerator

bull improvement of the quality and intensity of stable and radioactive beams (48Ca ndash 25divide3 pA )

bull providing of a smooth variation of energy of ions

in the range 08 ndash 27 MeVA

bull decrease in the consumption of rare isotopes bull decrease in power consumption

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

Working Diagram of the DC280 Cyclotron

Ion source DECRIS-4DECRIS-4 - 14 GHz - 14 GHzDECRIS-SC3 - 18 GHz- 18 GHz

Injecting beam potential Up to 100 kV

AZ range 4divide7

Energy 4divide8 MeVn

Magnetic field level 06divide135 T

K factor 280

Gap between plugs 400 mm

Valleyhill gap 500208 mmmm

Magnet weight 1000 t

Magnet power 300 kW

Dee voltage 2x130 kV

RF power consumption 2x30 kW

Flat-top dee voltage 2x14 kV

DC280 Main Parameters

Flerovlab Building 131

New Experimental Building with DC280 accelerator complex

Basement Rooms

First Floor

Second Floor

Third floor

SHE factory

Building computer model

DC280 Cyclotron intensity of some typical ion beams

20Ne 1middot1014 pps

48Ca 6middot1013 pps

50Ti 3middot1013 pps

70Zn 25middot1013 pps

86Kr 3middot1013 pps

100Mo 2middot1012 pps

124Sn 2middot1012 pps

136Xe 2middot1013 pps

208Pb 1middot1012 pps

238U 1middot1011 pps

FLNR

Schedule of the SHE factory creation

Modernization of the U400 accelerator

bull improvement of the quality and intensity of stable and radioactive beams (48Ca ndash 25divide3 pA )

bull providing of a smooth variation of energy of ions

in the range 08 ndash 27 MeVA

bull decrease in the consumption of rare isotopes bull decrease in power consumption

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

Ion source DECRIS-4DECRIS-4 - 14 GHz - 14 GHzDECRIS-SC3 - 18 GHz- 18 GHz

Injecting beam potential Up to 100 kV

AZ range 4divide7

Energy 4divide8 MeVn

Magnetic field level 06divide135 T

K factor 280

Gap between plugs 400 mm

Valleyhill gap 500208 mmmm

Magnet weight 1000 t

Magnet power 300 kW

Dee voltage 2x130 kV

RF power consumption 2x30 kW

Flat-top dee voltage 2x14 kV

DC280 Main Parameters

Flerovlab Building 131

New Experimental Building with DC280 accelerator complex

Basement Rooms

First Floor

Second Floor

Third floor

SHE factory

Building computer model

DC280 Cyclotron intensity of some typical ion beams

20Ne 1middot1014 pps

48Ca 6middot1013 pps

50Ti 3middot1013 pps

70Zn 25middot1013 pps

86Kr 3middot1013 pps

100Mo 2middot1012 pps

124Sn 2middot1012 pps

136Xe 2middot1013 pps

208Pb 1middot1012 pps

238U 1middot1011 pps

FLNR

Schedule of the SHE factory creation

Modernization of the U400 accelerator

bull improvement of the quality and intensity of stable and radioactive beams (48Ca ndash 25divide3 pA )

bull providing of a smooth variation of energy of ions

in the range 08 ndash 27 MeVA

bull decrease in the consumption of rare isotopes bull decrease in power consumption

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

Flerovlab Building 131

New Experimental Building with DC280 accelerator complex

Basement Rooms

First Floor

Second Floor

Third floor

SHE factory

Building computer model

DC280 Cyclotron intensity of some typical ion beams

20Ne 1middot1014 pps

48Ca 6middot1013 pps

50Ti 3middot1013 pps

70Zn 25middot1013 pps

86Kr 3middot1013 pps

100Mo 2middot1012 pps

124Sn 2middot1012 pps

136Xe 2middot1013 pps

208Pb 1middot1012 pps

238U 1middot1011 pps

FLNR

Schedule of the SHE factory creation

Modernization of the U400 accelerator

bull improvement of the quality and intensity of stable and radioactive beams (48Ca ndash 25divide3 pA )

bull providing of a smooth variation of energy of ions

in the range 08 ndash 27 MeVA

bull decrease in the consumption of rare isotopes bull decrease in power consumption

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

Basement Rooms

First Floor

Second Floor

Third floor

SHE factory

Building computer model

DC280 Cyclotron intensity of some typical ion beams

20Ne 1middot1014 pps

48Ca 6middot1013 pps

50Ti 3middot1013 pps

70Zn 25middot1013 pps

86Kr 3middot1013 pps

100Mo 2middot1012 pps

124Sn 2middot1012 pps

136Xe 2middot1013 pps

208Pb 1middot1012 pps

238U 1middot1011 pps

FLNR

Schedule of the SHE factory creation

Modernization of the U400 accelerator

bull improvement of the quality and intensity of stable and radioactive beams (48Ca ndash 25divide3 pA )

bull providing of a smooth variation of energy of ions

in the range 08 ndash 27 MeVA

bull decrease in the consumption of rare isotopes bull decrease in power consumption

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

First Floor

Second Floor

Third floor

SHE factory

Building computer model

DC280 Cyclotron intensity of some typical ion beams

20Ne 1middot1014 pps

48Ca 6middot1013 pps

50Ti 3middot1013 pps

70Zn 25middot1013 pps

86Kr 3middot1013 pps

100Mo 2middot1012 pps

124Sn 2middot1012 pps

136Xe 2middot1013 pps

208Pb 1middot1012 pps

238U 1middot1011 pps

FLNR

Schedule of the SHE factory creation

Modernization of the U400 accelerator

bull improvement of the quality and intensity of stable and radioactive beams (48Ca ndash 25divide3 pA )

bull providing of a smooth variation of energy of ions

in the range 08 ndash 27 MeVA

bull decrease in the consumption of rare isotopes bull decrease in power consumption

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

Second Floor

Third floor

SHE factory

Building computer model

DC280 Cyclotron intensity of some typical ion beams

20Ne 1middot1014 pps

48Ca 6middot1013 pps

50Ti 3middot1013 pps

70Zn 25middot1013 pps

86Kr 3middot1013 pps

100Mo 2middot1012 pps

124Sn 2middot1012 pps

136Xe 2middot1013 pps

208Pb 1middot1012 pps

238U 1middot1011 pps

FLNR

Schedule of the SHE factory creation

Modernization of the U400 accelerator

bull improvement of the quality and intensity of stable and radioactive beams (48Ca ndash 25divide3 pA )

bull providing of a smooth variation of energy of ions

in the range 08 ndash 27 MeVA

bull decrease in the consumption of rare isotopes bull decrease in power consumption

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

Third floor

SHE factory

Building computer model

DC280 Cyclotron intensity of some typical ion beams

20Ne 1middot1014 pps

48Ca 6middot1013 pps

50Ti 3middot1013 pps

70Zn 25middot1013 pps

86Kr 3middot1013 pps

100Mo 2middot1012 pps

124Sn 2middot1012 pps

136Xe 2middot1013 pps

208Pb 1middot1012 pps

238U 1middot1011 pps

FLNR

Schedule of the SHE factory creation

Modernization of the U400 accelerator

bull improvement of the quality and intensity of stable and radioactive beams (48Ca ndash 25divide3 pA )

bull providing of a smooth variation of energy of ions

in the range 08 ndash 27 MeVA

bull decrease in the consumption of rare isotopes bull decrease in power consumption

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

SHE factory

Building computer model

DC280 Cyclotron intensity of some typical ion beams

20Ne 1middot1014 pps

48Ca 6middot1013 pps

50Ti 3middot1013 pps

70Zn 25middot1013 pps

86Kr 3middot1013 pps

100Mo 2middot1012 pps

124Sn 2middot1012 pps

136Xe 2middot1013 pps

208Pb 1middot1012 pps

238U 1middot1011 pps

FLNR

Schedule of the SHE factory creation

Modernization of the U400 accelerator

bull improvement of the quality and intensity of stable and radioactive beams (48Ca ndash 25divide3 pA )

bull providing of a smooth variation of energy of ions

in the range 08 ndash 27 MeVA

bull decrease in the consumption of rare isotopes bull decrease in power consumption

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

DC280 Cyclotron intensity of some typical ion beams

20Ne 1middot1014 pps

48Ca 6middot1013 pps

50Ti 3middot1013 pps

70Zn 25middot1013 pps

86Kr 3middot1013 pps

100Mo 2middot1012 pps

124Sn 2middot1012 pps

136Xe 2middot1013 pps

208Pb 1middot1012 pps

238U 1middot1011 pps

FLNR

Schedule of the SHE factory creation

Modernization of the U400 accelerator

bull improvement of the quality and intensity of stable and radioactive beams (48Ca ndash 25divide3 pA )

bull providing of a smooth variation of energy of ions

in the range 08 ndash 27 MeVA

bull decrease in the consumption of rare isotopes bull decrease in power consumption

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

FLNR

Schedule of the SHE factory creation

Modernization of the U400 accelerator

bull improvement of the quality and intensity of stable and radioactive beams (48Ca ndash 25divide3 pA )

bull providing of a smooth variation of energy of ions

in the range 08 ndash 27 MeVA

bull decrease in the consumption of rare isotopes bull decrease in power consumption

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

Modernization of the U400 accelerator

bull improvement of the quality and intensity of stable and radioactive beams (48Ca ndash 25divide3 pA )

bull providing of a smooth variation of energy of ions

in the range 08 ndash 27 MeVA

bull decrease in the consumption of rare isotopes bull decrease in power consumption

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

Working Diagram of the U400R Cyclotronwith working points U400 Cyclotron

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

U400 48Ca beam intensity

1985 divide 2011 B

eam

Int

ensi

ty

pmicroA

Year

U400R

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

Parameters of U400 and U400R typical ion

U400

Ion Ion energy[MeVu]

Output intensity

4 He 1+ - -6 He 1+ 11 3107 pps8 He 1+ 79 -16 O 2+ 57 79 5 pμA18O3+ 78 105 158 44 pμA40 Ar 4+ 38 51 17 pμA48 Ca 5+ 37 53 12 pμA48Ca9+ 89 11 177 1 pμA50 Ti 5+ 36 51 04 pA58 Fe 6+ 38 54 07 pA84Kr8+ 31 44 03 pμA136Xe14+ 33 46 69 008 pμA

U400R (expected)

Ion Ion energy[MeVu]

Output intensity

4 He 1+ 64 27 23 pA 6 He 1+ 28 144 108 pps8 He 1+ 16 8 105 pps16 O 2+ 16 8 195 pA 16 O 4+ 64 27 58 pA 40 Ar 4+ 1 51 10 pA48 Ca 6+ 16 8 25 pA48 Ca 7+ 21 11 21 pA50 Ti 10+ 41 21 1 pA58 Fe 7+ 12 75 1 pA84 Kr 7+ 08 35 14 pA132 Xe 11+ 08 35 09 pA238 U 27+ 15 8 01 pA

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

U400 accelerator complex Planning Lay-out

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

U400R Median plane level Second floor

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

U400R Building Cross-section

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

SHE factory

U400R + SHE factory

U400R

Building 131

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

U400 U400R Schedule

Hall design Building

U400 U400Rassembling

U400 beam on

U400R beam on

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

2011 Project

Areas for set-ups 400 м2 1500 м2

Areas for electronics 300 м2 600 м2

Areas for technical equipment

670 м2 1300 м2

Number of radiation isolated halls

1 6

U400 U400R hall reconstruction results

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32

THANKS FOR YOUR ATTENTION

• Slide 1
• Slide 2
• Slide 3
• Slide 4
• Slide 5
• Slide 6
• Slide 7
• Slide 8
• Slide 9
• Slide 10
• Slide 11
• Slide 12
• Slide 13
• Slide 14
• Slide 15
• Slide 16
• Slide 17
• Slide 18
• Slide 19
• Slide 20
• Slide 21
• Slide 22
• Slide 23
• Slide 24
• Slide 27
• Slide 28
• Slide 29
• Slide 30
• Slide 31
• Slide 32