PANDA The conceptual design of the control Dewar

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Presentation transcript:

PANDA The conceptual design of the control Dewar PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov

PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov PANDA control Dewar The PANDA control Dewar is designed to the liquid and gas helium supply the solenoid in accordance with the flow scheme. TL - transfer lines (TL) connecting refrigerator and control Dewar - transfer line (Chimney) connecting the vacuum vessels of the solenoid cryostat and control Dewar D1600 2080 Control Dewar Chimney Figure 1. General view of the control Dewar. PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov

Figure 2. The main components of the control Dewar. Control Dewar consists of: • a vessel for liquid helium (~480L); • current leads; • thermal shields cooled by gaseous helium; • valves, gauges; • vacuum shell. 4 2 1 5 3 Figure 2. The main components of the control Dewar. PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov

Figure 3. Process Flow Diagram of the PANDA cryogenic system. PANDA solenoid 2017, Flowscheme with comments of GSI Selected valves that will be used when moving the detector from in the beam position to the assembling area. Figure 3. Process Flow Diagram of the PANDA cryogenic system. PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov

The stages of Assembly of the PANDA control Dewar: 1. Installation of pipelines on the cap plate of the control Dewar Current leads Vessel cap plate -Pipeline 4,2K F red color -Pipeline 5K R violet color -Pipeline 40K F cyan color -Pipeline 80K R blue color He vessel Figure 4. The stage 1. PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov

The stages of Assembly of the PANDA control Dewar: 2. Installation of pipelines on the cap plate of the control Dewar 1100 4,2K F 5K R 40K F 80K R 1850 Figure 4. The stage 2. PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov

The stages of Assembly of the PANDA control Dewar: 3. Installation of the thermal shields in the vacuum shell Thermal shield Vacuum shell 80K Figure 5. The stage 3. PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov

Design of the thermal shields Al sheet S=3mm Al profile Ø14 Ʊ-type 1400 Ball support Figure 6. thermal shield. PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov

The stages of Assembly of the PANDA control Dewar: 3. Installation pipelines into the thermal shields of the control Dewar Figure 7. The stage 3. PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov

PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov The interface of the PANDA control Dewar. Connection place of the cryogenic system to move the PANDA detector. TL Bellows unit Shift the bellows unit; Combine the pipes in accordance with the flow scheme; -connect pipes; Install super insulation; Install the bellows unit in place; Connection joints Vacuum barrier Control Dewar PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov

The interface of the PANDA control Dewar – solenoid cryostat Shift the bellows unit; Combine the pipes in accordance with the flow scheme; -connect the superconductor busbars; -connect pipes by welding; Install MLI super insulation covers; Install the bellows unit in place. Control Dewar Chimney PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov

PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov The Chimney design: Chimney Bellows unit Flange ISO320RBR Thermal shield Spacer Pipelines Flange ISO320RBR Superconductor PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov

PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov The TL design: TL Metal Hoses DN20 Flange ISO250BF Metal Hoses DN200 Bellows unit Flange ISO320RBR The end of the supplying TL has the ability to 3D move ±300mm The bellows unit has the ability to move 450 mm up PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov

Thank you for your attention PANDA Collaboration Meeting 04-08.06.2018, BINP, M.Kholopov